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<value subtitle="Physical properties of crystals">D</value>
<value subtitle="Subperiodic group symmetry">E</value>
<value subtitle="Crystallography of biological macromolecules">F</value>
<value subtitle="Definition and exchange of crystallographic data">G</value>
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<aug><div class="aug">
<div class="au">
<b> <span class="au">B. Souvignier</span><a class="linkclass" href="#a"><sup>a</sup></a><a class="linkclass" href="#cor"><sup>*</sup></a></b>
</div>

<div class="aff">
<p><span class="small"><a class="linkclass" name="a"><sup><b>a</b></sup></a>Radboud University Nijmegen, Faculty of Science, Mathematics and Computing Science, Institute for Mathematics, Astrophysics and Particle Physics, Postbus 9010, 6500 GL <cty>Nijmegen</cty>, <span class="cny">The Netherlands</span><br/><a name="cor">Correspondence e-mail:</a>&#160;<a class="linkclass" href="mailto:souvi@math.ru.nl">souvi@math.ru.nl</a></span></p>
</div>

</div>
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<span class="au">B. Souvignier</span>
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<aff id="a"><a class="linkclass" name="a"><sup><b>a</b></sup></a>Radboud University Nijmegen, Faculty of Science, Mathematics and Computing Science, Institute for Mathematics, Astrophysics and Particle Physics, Postbus 9010, 6500 GL <cty>Nijmegen</cty>, <span class="cny">The Netherlands</span></aff>
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<aff id="a" upa="Radboud University Nijmegen, Faculty of Science, Mathematics and Computing Science, Institute for Mathematics, Astrophysics and Particle Physics, Postbus 9010, 6500 GL Nijmegen, The Netherlands">Radboud University Nijmegen, Faculty of Science, Mathematics and Computing Science, Institute for Mathematics, Astrophysics and Particle Physics, Postbus 9010, 6500 GL <cty>Nijmegen</cty>, <span class="cny">The Netherlands</span></aff>
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<abs><div id="abs"><p>This chapter provides an introduction to the structure and classification of crystallographic space groups. Viewing space groups as groups of affine mappings which leave a crystal pattern invariant as a whole suggests a natural decomposition of a space group into its translation subgroup and its point group, since an affine mapping is composed from a linear part and a translation part. Starting with the translation part, one observes that the vectors by which the translations in the space group move the crystal pattern form a lattice, and we discuss fundamental concepts concerned with lattices, such as the metric tensor, the unit cell and the distinction into primitive and centred lattices. We then proceed to the point groups, which are formed by the linear parts of the affine mappings contained in a space group. A crucial point is that the point group acts on the translation lattice and the interplay between point groups and lattices is discussed in detail. In particular, the distinction between symmorphic and non-symmorphic groups is explained. The final part of this chapter deals with various schemes in which crystallographic space groups are classified. The most important of these are the classification into space-group types, geometric crystal classes and Bravais types of lattices.</p>
</div>
</abs>
<kwdg><div id="kwdg">
<p><span class="kwdg_head">Keywords: </span>space groups; space-group types; affine mappings; point groups; lattices; reciprocal lattice; unit cells; classification of space groups; Bravais types of lattices; coset decomposition; geometric crystal classes; arithmetic crystal classes; crystal families; crystal systems; lattice systems.</p></div>
.</kwdg>
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<bdy>
<subch>
<div id="divsec1o3o1" class="sec1" secnum="1.3.1" fpage="22" lpage="22">
<div class="sectionheaders">
<h3 class="sectionheaders"><a name="sec1o3o1"><tree level="1"/></a>1.3.1. Introduction</h3>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o1.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o1" secnum="1.3.1">Introduction</st>
<p>We recall from Chapter <related volume="A" revision="c" chnum="1.2" url="/Ac/ch1o2v0001/"><relchtitle>Crystallographic symmetry</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau></related>1.2<a href="/Ac/ch1o2v0001/"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 that an <span class="it"><i>isometry</i></span><indexg><index id="acch1o3index00001" significance="standard" type="s">isometry</index></indexg> is a mapping of the point space <img src="/teximages/acpre6/acpre6fi1.svg" alt="[{\bb E}^n]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 15px;"/> which preserves distances and angles. From the mathematical viewpoint, <img src="/teximages/acpre6/acpre6fi1.svg" alt="[{\bb E}^n]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 15px;"/> is an <span class="it"><i>affine space</i></span><indexg><index significance="standard" id="acch1o3index00002" type="s">affine space</index></indexg> in which two points differ by a unique vector in the underlying <span class="it"><i>vector space</i></span><indexg><index type="s" significance="standard" id="acch1o3index00003">vector space</index></indexg> <img src="/teximages/acpre6/acpre6fi2.svg" alt="[{\bb V}^n]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227148pt;"/>. The crucial difference between these two types of spaces is that in an affine space no point is distinguished, whereas in a vector space the zero vector plays a special role, namely as the identity element for the addition of vectors. After choosing an origin <img src="/teximages/acch1o3/acch1o3fi4.svg" alt="[O]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/>, the points of the affine space <img src="/teximages/acpre6/acpre6fi1.svg" alt="[{\bb E}^n]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 15px;"/> are in one-to-one correspondence with the vectors of <img src="/teximages/acpre6/acpre6fi2.svg" alt="[{\bb V}^n]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227148pt;"/> by identifying a point <img src="/teximages/acch1o2/acch1o2fi79.svg" alt="[P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with the difference vector <img src="/teximages/acch1o3/acch1o3fi8.svg" alt="[\overrightarrow{OP}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389000000002pt;"/>.</p>
<p>A <span class="it"><i>crystallographic space-group operation</i></span><indexg><index type="s" id="acch1o3index00004" significance="standard">crystallographic space-group operation</index><index id="acch1o3index00005" significance="standard" type="s">space-group operation<index id="acch1o3index00006" significance="standard" type="s">crystallographic</index></index><index significance="standard" id="acch1o3index00007" type="s">space groups</index></indexg> is an isometry that maps a crystal pattern onto itself. Since isometries are invertible and the composition of two isometries leaves a crystal pattern invariant as a whole if the two single isometries do so, the space-group operations form a group <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, called a <span class="it"><i>crystallographic space group</i></span><indexg><index significance="standard" id="acch1o3index00008" type="s">crystallographic space group</index><index type="s" id="acch1o3index00009" significance="standard">space groups<index type="s" significance="standard" id="acch1o3index00010">crystallographic</index></index></indexg>.</p>
<p>As a mapping of points in an affine space, a space-group operation is an affine mapping and is thus composed of a linear mapping of the underlying vector space and a translation. Once a coordinate system has been chosen, space-group operations are conveniently represented as <span class="it"><i>matrix&#8211;column pairs</i></span><indexg><index id="acch1o3index00011" significance="standard" type="s">matrix&#8211;column pair</index></indexg> <img src="/teximages/abch11o2/abch11o2fi11.svg" alt="[({\bi W}, {\bi w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, where <img src="/teximages/acch1o2/acch1o2fi108.svg" alt="[{\bi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/> is the <span class="it"><i>linear part</i></span><indexg><index type="s" id="acch1o3index00012" significance="standard">space-group operation<index significance="standard" id="acch1o3index00013" type="s">linear part</index></index><index type="s" significance="standard" id="acch1o3index00014">linear part of a space-group operation</index></indexg> and <img src="/teximages/abch12o2/abch12o2fi15.svg" alt="[{\bi w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/> the <span class="it"><i>translation part</i></span><indexg><index id="acch1o3index00015" significance="standard" type="s">space-group operation<index id="acch1o3index00016" significance="standard" type="s">translation part</index></index><index id="acch1o3index00017" significance="standard" type="s">translation part of a space-group operation</index></indexg> and a point with coordinates <img src="/teximages/abch8o1/abch8o1fi65.svg" alt="[{\bi x}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/> is mapped to <img src="/teximages/acch1o3/acch1o3fi14.svg" alt="[{\bi W} {\bi x} + {\bi w} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/> (<span class="it"><i>cf.</i></span> Section <related volume="A" revision="c" chnum="1.2" url="/Ac/ch1o2v0001/#sec1o2o2"><relchtitle>Crystallographic symmetry</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau></related>1.2.2<a href="/Ac/ch1o2v0001/#sec1o2o2"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
).</p>
<p>A translation is a matrix&#8211;column pair of the form <img src="/teximages/acch1o3/acch1o3fi15.svg" alt="[({\bi I}, {\bi w}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, where <img src="/teximages/acch1o3/acch1o3fi16.svg" alt="[{\bi I}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is the unit matrix and all translations taken together form the <span class="it"><i>translation subgroup</i></span><indexg><index type="s" significance="standard" id="acch1o3index00018">translation subgroup</index><index type="s" significance="standard" id="acch1o3index00019">subgroups<index type="s" significance="standard" id="acch1o3index00020">translation subgroup</index></index></indexg> <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. The translation subgroup is an infinite group that forms an abelian normal subgroup of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. The factor group <img src="/teximages/acch1o3/acch1o3fi20.svg" alt="[{\cal G}/{\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> is a finite group that can be identified with the group of linear parts of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> <span class="it"><i>via</i></span> the mapping <img src="/teximages/acch1o3/acch1o3fi22.svg" alt="[({\bi W}, {\bi w}) \,\mapsto\, {\bi W} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, which simply forgets about the translation part. The group <img src="/teximages/acch1o3/acch1o3fi23.svg" alt="[{\cal P} = \{ {\bi W} \mid ({\bi W}, {\bi w}) \in {\cal G}\} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> of linear parts occurring in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is called the <span class="it"><i>point group</i></span><indexg><index type="s" id="acch1o3index00021" significance="standard">point groups</index></indexg> <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>.</p>
<p>The representation of space-group operations as matrix&#8211;column pairs is clearly adapted to the fact that space groups can be built from these two parts, the translation subgroup and the point group. This viewpoint will be discussed in detail in Section 1.3.3<secr id="sec1o3o3"/>. It allows one to treat space groups in many aspects analogously to finite groups, although, due to the infinite translation subgroup, they are of course infinite groups.</p>
</div>

<div id="divsec1o3o2" class="sec1" secnum="1.3.2" fpage="22" lpage="28">
<div class="sectionheaders">
<h3 class="sectionheaders"><a name="sec1o3o2"><tree level="1"/></a>1.3.2. Lattices<indexg><index type="s" id="acch1o3index00022" significance="standard">lattice</index></indexg></h3>
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</div>
<st secid="sec1o3o2" secnum="1.3.2">Lattices<indexg><index type="s" id="acch1o3index00022" significance="standard">lattice</index></indexg></st>
<p>A crystal pattern is defined to be periodic in three linearly independent directions, which means that it is invariant under translations in three linearly independent directions. This periodicity implies that the crystal pattern extends infinitely in all directions. Since the atoms of a crystal form a discrete pattern in which two different points have a certain minimal distance, the translations that fix the crystal pattern as a whole cannot have arbitrarily small lengths. If <img src="/teximages/acch1o3/acch1o3fi27.svg" alt="[{\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> is a vector such that the crystal pattern is invariant under a translation by <img src="/teximages/acch1o3/acch1o3fi27.svg" alt="[{\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, the periodicity implies that the pattern is invariant under a translation by <img src="/teximages/acch1o3/acch1o3fi29.svg" alt="[m {\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> for every integer <span class="it"><i>m</i></span>. Furthermore, if a crystal pattern is invariant under translations by <img src="/teximages/acch1o3/acch1o3fi27.svg" alt="[{\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> and <img src="/teximages/acch1o3/acch1o3fi31.svg" alt="[{\bf w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, it is also invariant by the composition of these two translations, which is the translation by <img src="/teximages/acch1o3/acch1o3fi32.svg" alt="[{\bf v} + {\bf w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>. This shows that the set of vectors by which the translations in a space group move the crystal pattern is closed under taking integral linear combinations. This property is formalized by the mathematical concept of a <span class="it"><i>lattice</i></span> and the translation subgroups of space groups are best understood by studying their corresponding lattices. These lattices capture the periodic nature of the underlying crystal patterns and reflect their geometric properties.</p>

<div id="divsec1o3o2o1" class="sec2" secnum="1.3.2.1" fpage="22" lpage="23">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o2o1"><tree level="2"/></a>1.3.2.1. Basic properties of lattices</h4>
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</div>
<st secid="sec1o3o2o1" secnum="1.3.2.1">Basic properties of lattices</st>
<p>The two-dimensional vector space <img src="/teximages/acch1o3/acch1o3fi33.svg" alt="[{\bb V}^2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> is the space of columns <img src="/teximages/acch1o3/acch1o3fi34.svg" alt="[\pmatrix{ x \cr y }]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.39155100000001pt;"/> with two real components <img src="/teximages/acch1o3/acch1o3fi35.svg" alt="[x,y \in {\bb R}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> and the three-dimensional vector space <img src="/teximages/acch1o3/acch1o3fi36.svg" alt="[{\bb V}^3 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> is the space of columns <img src="/teximages/acch1o3/acch1o3fi37.svg" alt="[\pmatrix{ x \cr y \cr z }]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -14.933976pt;"/> with three real components <img src="/teximages/acch1o3/acch1o3fi38.svg" alt="[x,y,z \in {\bb R}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/>. Analogously, the <img src="/teximages/acch1o3/acch1o3fi39.svg" alt="[n]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999995pt;"/>-dimensional vector space <img src="/teximages/acpre6/acpre6fi2.svg" alt="[{\bb V}^n]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227148pt;"/> is the space of columns <img src="/teximages/acch1o3/acch1o3fi41.svg" alt="[{\bf v} = \pmatrix{v_1 \cr \vdots \cr v_n }]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -17.922798pt;"/> with <span class="it"><i>n</i></span> real components.</p>
<p>For the sake of clarity we will restrict our discussions to three-dimensional (and occasionally two-dimensional) space. The generalization to <span class="it"><i>n</i></span>-dimensional space is straightforward and only requires dealing with columns of <span class="it"><i>n</i></span> instead of three components and with bases consisting of <span class="it"><i>n</i></span> instead of three basis vectors.</p>
<enun id="definition1o3o2o1o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o2o1" secnum="enun1.3.2.1">Definition</st>
<p>For vectors <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> forming a basis of the three-dimensional vector space <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/>, the set <span class="fd"><a name="fdu1o3o2o1"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd1.svg" alt="[ {\bf L}: = \{ l {\bf a} + m {\bf b} + n {\bf c} \mid l,m,n \in {\bb Z} \} ]" class="mathimage" style="max-width: 100%; height: auto; width: 196px;"/></span>of all <span class="it"><i>integral</i></span> linear combinations of <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is called a <span class="it"><i>lattice</i></span> in <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> and the vectors <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> are called a <span class="it"><i>lattice basis</i></span><indexg><index type="s" significance="standard" id="acch1o3index00023">lattice basis</index><index id="acch1o3index00024" significance="standard" type="s">basis</index></indexg> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
</enun>
<p>
</p>
<p>It is inherent in the definition of a crystal pattern that the translation vectors of the translations leaving the pattern invariant are closed under taking integral linear combinations. Since the crystal pattern is assumed to be discrete, it follows that all translation vectors can be written as integral linear combinations of a finite generating set. The fundamental theorem on finitely generated abelian groups (see <span class="it"><i>e.g.</i></span> Chapter 21 in Armstrong, 1997<bbr id="bb1"/>) asserts that in this situation a set of three translation vectors <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> can be found such that all translation vectors are integral linear combinations of these three vectors. This shows that the translation vectors of a crystal pattern form a lattice with lattice basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> in the sense of the definition above. </p>
<p>By definition, a lattice is determined by a lattice basis. Note, however, that every two- or three-dimensional lattice has infinitely many bases.</p>
<enun id="example1o3o2o1o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o2o1" secnum="enun1.3.2.1">Example</st>
<p>The square lattice<span class="fd"><a name="fdu4"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd2.svg" alt="[{\bf L} = {\bb Z}^2 = \left\{ \pmatrix{ m \cr n } \mid m, n \in {\bb Z}\right\} ]" class="mathimage" style="max-width: 100%; height: auto; width: 176px;"/></span>in <img src="/teximages/acch1o3/acch1o3fi33.svg" alt="[{\bb V}^2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> has the vectors<span class="fd"><a name="fdu5"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd3.svg" alt="[{\bf a} = \pmatrix{ 1 \cr 0 },\quad {\bf b} = \pmatrix{ 0 \cr 1 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 133px;"/></span>as its standard lattice basis. But<span class="fd"><a name="fdu6"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd4.svg" alt="[{\bf a}' = \pmatrix{ 1 \cr -2 },\quad {\bf b}' = \pmatrix{ -2 \cr 3 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 162px;"/></span>is also a lattice basis of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>: on the one hand <img src="/teximages/acch1o3/acch1o3fi52.svg" alt="[{\bf a}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> and <img src="/teximages/abch4o3/abch4o3fi270.svg" alt="[{\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> are integral linear combinations of <img src="/teximages/acch1o3/acch1o3fi54.svg" alt="[{\bf a}, {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> and are thus contained in <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. On the other hand<span class="fd"><a name="fdu7"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd5.svg" alt="[-3 {\bf a}' - 2 {\bf b}' = \pmatrix{ -3 \cr 6 } + \pmatrix{ 4 \cr -6 } = \pmatrix{ 1 \cr 0 } = {\bf a} ]" class="mathimage" style="max-width: 100%; height: auto; width: 256px;"/></span>and<span class="fd"><a name="fdu8"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd6.svg" alt="[-2 {\bf a}' - {\bf b}' = \pmatrix{ -2 \cr 4 } + \pmatrix{ 2 \cr -3 } = \pmatrix{ 0 \cr 1 } = {\bf b}, ]" class="mathimage" style="max-width: 100%; height: auto; width: 250px;"/></span>hence <img src="/teximages/abch15o2/abch15o2fi699.svg" alt="[{\bf a}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> and <img src="/teximages/abch15o2/abch15o2fi700.svg" alt="[{\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> are also integral linear combinations of <img src="/teximages/acch1o3/acch1o3fi58.svg" alt="[{\bf a}', {\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> and thus the two bases <img src="/teximages/acch1o3/acch1o3fi54.svg" alt="[{\bf a}, {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> and <img src="/teximages/acch1o3/acch1o3fi58.svg" alt="[{\bf a}', {\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> both span the same lattice (see Fig. 1.3.2.1<figr id="fig1o3o2o1" loc="float"/>).</p>
<figplace id="fig1o3o2o1"/>
</enun>
<p>
</p>
<p>The example indicates how the different lattice bases of a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> can be described. Recall that for a vector <img src="/teximages/acch1o3/acch1o3fi27.svg" alt="[{\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> = <img src="/teximages/acch1o3/acch1o3fi63.svg" alt="[x {\bf a} + y {\bf b} + z {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> the coefficients <img src="/teximages/abch10o1/abch10o1fi157.svg" alt="[x,y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> are called the <span class="it"><i>coordinates</i></span><indexg><index id="acch1o3index00025" significance="standard" type="s">coordinates and coordinate triplets</index></indexg> and the vector <img src="/teximages/acch1o3/acch1o3fi37.svg" alt="[\pmatrix{ x \cr y \cr z }]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -14.933976pt;"/> is called the <span class="it"><i>coordinate column</i></span> of <img src="/teximages/acch1o3/acch1o3fi27.svg" alt="[{\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> with respect to the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>. The coordinate columns of the vectors in <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with respect to a lattice basis are therefore simply columns with three integral components. In particular, if we take a second lattice basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, then the coordinate columns of <img src="/teximages/abch4o3/abch4o3fi269.svg" alt="[{\bf a}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>, <img src="/teximages/abch4o3/abch4o3fi270.svg" alt="[{\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>, <img src="/teximages/abch4o3/abch4o3fi274.svg" alt="[{\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>with respect to the first basis are columns of integers and thus the basis transformation <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> such that <img src="/teximages/acch1o3/acch1o3fi75.svg" alt="[({\bf a}', {\bf b}', {\bf c}') = ({\bf a}, {\bf b}, {\bf c}) {\bi P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is an integral 3 &#215; 3 matrix. But if we interchange the roles of the two bases, they are related by the inverse transformation <img src="/teximages/acch1o3/acch1o3fi76.svg" alt="[{\bi P}^{-1} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.00000000102796e-06pt;"/>, <span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi77.svg" alt="[({\bf a}, {\bf b}, {\bf c}) = ({\bf a}', {\bf b}', {\bf c}') {\bi P}^{-1} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, and the argument given above asserts that <img src="/teximages/acch1o3/acch1o3fi78.svg" alt="[{\bi P}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.00000000102796e-06pt;"/> is also an integral matrix. Now, on the one hand <img src="/teximages/acch1o3/acch1o3fi79.svg" alt="[\det {\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.119104999999996pt;"/> and <img src="/teximages/acch1o3/acch1o3fi80.svg" alt="[\det {\bi P}^{-1} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.119106pt;"/> are both integers (being determinants of integral matrices), on the other hand <img src="/teximages/acch1o3/acch1o3fi81.svg" alt="[\det {\bi P}^{-1} = 1 / \det {\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988793pt;"/>. This is only possible if <img src="/teximages/acch1o3/acch1o3fi82.svg" alt="[\det {\bi P} = \pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.119104999999996pt;"/>.</p>
<p>Summarizing, the different lattice bases of a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> are obtained by transforming a single lattice basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with integral transformation matrices <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> such that <img src="/teximages/acch1o3/acch1o3fi82.svg" alt="[\det {\bi P} = \pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.119104999999996pt;"/>.</p>
</div>

<div id="divsec1o3o2o2" class="sec2" secnum="1.3.2.2" fpage="23" lpage="24">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o2o2"><tree level="2"/></a>1.3.2.2. Metric properties</h4>
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</div>
<st secid="sec1o3o2o2" secnum="1.3.2.2">Metric properties</st>
<p>In the three-dimensional vector space <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/>, the <span class="it"><i>norm</i></span> or <span class="it"><i>length</i></span> of a vector <img src="/teximages/acch1o3/acch1o3fi88.svg" alt="[{\bf v} = \pmatrix{ v_x \cr v_y \cr v_z }]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.348265pt;"/> is (due to Pythagoras' theorem) given by <span class="fd"><a name="fdu1o3o2o2"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd7.svg" alt="[ |{\bf v}| = \sqrt{v_x^2 + v_y^2 + v_z^2}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 114px;"/></span>From this, the <span class="it"><i>scalar product</i></span> <span class="fd"><a name="fdu1o3o2o3"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd8.svg" alt="[ {\bf v} \cdot {\bf w} = v_x w_x + v_y w_y + v_z w_z \ {\rm for }\ {\bf v} = \pmatrix{ v_x \cr v_y \cr v_z }, {\bf w} = \pmatrix{ w_x \cr w_y \cr w_z } ]" class="mathimage" style="max-width: 100%; height: auto; width: 319px;"/></span>is derived, which allows one to express angles by <span class="fd"><a name="fdu1o3o2o4"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd9.svg" alt="[ \cos \angle ({\bf v}, {\bf w}) = {{{\bf v} \cdot {\bf w}}\over{| {\bf v} | \, | {\bf w} |}}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 126px;"/></span></p>
<p>The definition of a norm function for the vectors turns <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> into a <span class="it"><i>Euclidean space</i></span>. A lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> that is contained in <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> inherits the metric properties of this space. But for the lattice, these properties are most conveniently expressed with respect to a lattice basis. It is customary to choose basis vectors <span class="b"><b>a</b></span>, <span class="b"><b>b</b></span>, <span class="b"><b>c</b></span> which define a right-handed coordinate system<indexg><index id="acch1o3index00026" significance="standard" type="s">coordinate system</index></indexg>, <span class="it"><i>i.e.</i></span> such that the matrix with columns <span class="b"><b>a</b></span>, <span class="b"><b>b</b></span>, <span class="b"><b>c</b></span> has a positive determinant.</p>
<enun id="definition1o3o2o2o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o2o2" secnum="enun1.3.2.2">Definition</st>
<p>For a lattice <img src="/teximages/acch1o3/acch1o3fi92.svg" alt="[{\bf L} \subseteq {\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.637859pt;"/> with lattice basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> the <span class="it"><i>metric tensor</i></span><indexg><index type="s" significance="standard" id="acch1o3index00027">metric tensor</index></indexg> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is the 3 &#215; 3 matrix <span class="fd"><a name="fdu1o3o2o5"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd10.svg" alt="[ {\bi G} = \pmatrix{ {\bf a} \cdot {\bf a} &amp; {\bf a} \cdot {\bf b} &amp; {\bf a} \cdot {\bf c} \cr {\bf b} \cdot {\bf a} &amp; {\bf b} \cdot {\bf b} &amp; {\bf b} \cdot {\bf c} \cr {\bf c} \cdot {\bf a} &amp; {\bf c} \cdot {\bf b} &amp; {\bf c} \cdot {\bf c} }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 169px;"/></span>If <img src="/teximages/acch1o1/acch1o1fi145.svg" alt="[{\bi A}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 10px;"/> is the 3 &#215; 3 matrix with the vectors <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> as its columns, then the metric tensor is obtained as the matrix product <img src="/teximages/acch1o3/acch1o3fi97.svg" alt="[{\bi G} = {\bi A}^{\rm T}\cdot {\bi A}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999997pt;"/>. It follows immediately that the metric tensor is a symmetric matrix, <span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi98.svg" alt="[{\bi G}^{\rm T} = {\bi G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999997pt;"/>.</p>
</enun>
<p>
</p>
<enun id="example1o3o2o2o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o2o2" secnum="enun1.3.2.2">Example</st>
<p>Let<span class="fd"><a name="fdu11"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd11.svg" alt="[{\bf a} = \pmatrix{ 1 \cr 1 \cr 1 },\quad {\bf b} = \pmatrix{ 1 \cr 1 \cr 0 },\quad {\bf c} = \pmatrix{ 1 \cr -1 \cr 0 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 232px;"/></span>be the basis of a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Then the metric tensor of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> (with respect to the given basis) is<span class="fd"><a name="fdu121"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd12.svg" alt="[{\bi G} = \pmatrix{ 3 &amp; 2 &amp; 0 \cr 2 &amp; 2 &amp; 0 \cr 0 &amp; 0 &amp; 2 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 113px;"/></span></p>
</enun>
<p>
</p>
<p>With the help of the metric tensor the scalar products of arbitrary vectors, given as linear combinations of the lattice basis, can be computed from their coordinate columns as follows: If <img src="/teximages/acch1o3/acch1o3fi101.svg" alt="[{\bf v} = x_1 {\bf a} + y_1 {\bf b} + z_1 {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> and <img src="/teximages/acch1o3/acch1o3fi102.svg" alt="[{\bf w} = x_2 {\bf a} + y_2 {\bf b} + z_2 {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/>, then <span class="fd"><a name="fdu1o3o2o6"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd13.svg" alt="[ {\bf v} \cdot {\bf w} = (x_1 \, y_1 \, z_1) \cdot {\bi G} \cdot \pmatrix{ x_2 \cr y_2 \cr z_2 }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 173px;"/></span></p>
<p>From this it follows how the metric tensor transforms under a basis transformation<indexg><index significance="standard" id="acch1o3index00028" type="s">basis transformation</index><index type="s" significance="standard" id="acch1o3index00029">transformation of basis</index></indexg> <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. If <img src="/teximages/acch1o3/acch1o3fi75.svg" alt="[({\bf a}', {\bf b}', {\bf c}') = ({\bf a}, {\bf b}, {\bf c}) {\bi P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, then the metric tensor <img src="/teximages/acch1o3/acch1o3fi105.svg" alt="[{\bi G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389000000001pt;"/> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with respect to the new basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is given by <span class="fd"><a name="fdu1o3o2o7"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd14.svg" alt="[ {\bi G}' = {\bi P}^{\rm T} \cdot {\bi G} \cdot {\bi P}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 91px;"/></span></p>
<p>An alternative way to specify the geometry of a lattice in <img src="/teximages/acch1o3/acch1o3fi36.svg" alt="[{\bb V}^3 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> is using the <span class="it"><i>cell parameters</i></span><indexg><index significance="standard" id="acch1o3index00030" type="s">cell parameters</index></indexg>, which are the lengths of the lattice basis vectors and the angles between them.</p>
<p/>
<enun id="definition1o3o2o2o3" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o2o2" secnum="enun1.3.2.2">Definition</st>
<p>For a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> in <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> with lattice basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> the <span class="it"><i>cell parameters</i></span> (also called <span class="it"><i>lattice parameters</i></span>, <span class="it"><i>lattice constants</i></span> or <span class="it"><i>metric parameters</i></span>) are given by the lengths <span class="fd"><a name="fdu1o3o2o8"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd15.svg" alt="[ a = | {\bf a} | = \sqrt{ {\bf a} \cdot {\bf a} }, \quad b = | {\bf b} | = \sqrt{ {\bf b} \cdot {\bf b} }, \quad c = | {\bf c} | = \sqrt{ {\bf c} \cdot {\bf c} } ]" class="mathimage" style="max-width: 100%; height: auto; width: 328px;"/></span>of the basis vectors and by the interaxial angles <span class="fd"><a name="fdu1o3o2o9"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd16.svg" alt="[ \alpha = \angle ({\bf b}, {\bf c}), \quad \beta = \angle ({\bf c}, {\bf a}), \quad \gamma = \angle ({\bf a}, {\bf b}). ]" class="mathimage" style="max-width: 100%; height: auto; width: 243px;"/></span></p>
</enun>
<p>
</p>
<p>Owing to the relation <img src="/teximages/acch1o3/acch1o3fi112.svg" alt="[{\bf v} \cdot {\bf w} = | {\bf v} | \, | {\bf w} | \, \cos \angle ({\bf v}, {\bf w}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> for the scalar product of two vectors, one can immediately write down the metric tensor in terms of the cell parameters: <span class="fd"><a name="fdu1o3o2o10"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd17.svg" alt="[ {\bi G} = \pmatrix{ a^2 &amp; a b \cos \gamma &amp; a c \cos \beta \cr a b \cos \gamma &amp; b^2 &amp; b c \cos \alpha \cr a c \cos \beta &amp; b c \cos \alpha &amp; c^2 }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 235px;"/></span></p>
</div>

<div id="divsec1o3o2o3" class="sec2" secnum="1.3.2.3" fpage="24" lpage="24">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o2o3"><tree level="2"/></a>1.3.2.3. Unit cells<indexg><index id="acch1o3index00031" significance="standard" type="s">unit cell</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o2o3.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o2o3" secnum="1.3.2.3">Unit cells<indexg><index id="acch1o3index00031" significance="standard" type="s">unit cell</index></indexg></st>
<p>A lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> can be used to subdivide <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> into cells of finite volume which all have the same shape. The idea is to define a suitable subset <img src="/teximages/acch1o3/acch1o3fi115.svg" alt="[{\bf C}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.226299999999997pt;"/> of <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> such that the translates of <img src="/teximages/acch1o3/acch1o3fi115.svg" alt="[{\bf C}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.226299999999997pt;"/> by the vectors in <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> cover <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> without overlapping. Such a subset <img src="/teximages/acch1o3/acch1o3fi115.svg" alt="[{\bf C}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.226299999999997pt;"/> is called a <span class="it"><i>unit cell</i></span> of <span class="b"><b>L</b></span>, or, in the more mathematically inclined literature, a <span class="it"><i>fundamental domain</i></span><indexg><index significance="standard" id="acch1o3index00032" type="s">fundamental domain</index></indexg> of <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> with respect to <img src="/teximages/acch1o3/acch1o3fi122.svg" alt="[{\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Two standard constructions for such unit cells are the <span class="it"><i>primitive unit cell</i></span> and the <span class="it"><i>Vorono&#239; domain</i></span> (which is also known by many other names).</p>
<enun id="definition1o3o2o3o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o2o3" secnum="enun1.3.2.3">Definition</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> be a lattice in <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> with lattice basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
<div id="l1o3o2o3o1" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o2o3o1o1"/><p>(i) The set <img src="/teximages/acch1o3/acch1o3fi126.svg" alt="[{\bf C}: = \{ x {\bf a} + y {\bf b} + z {\bf c} \mid 0 \leq x,y,z \,\lt\, 1 \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> is called the <span class="it"><i>primitive unit cell</i></span> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with respect to the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>. The primitive unit cell is the parallelepiped spanned by the vectors of the given basis.</p>
</li>
<li><a name="li1o3o2o3o1o2"/><p>(ii) The set <img src="/teximages/acch1o3/acch1o3fi129.svg" alt="[{\bf C}: = \{ {\bf w} \in {\bb V}^3 \mid |{\bf w}| \leq |{\bf w}-{\bf v}| \ {\rm for\ all }\ {\bf v} \in {\bf L} \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988793pt;"/> is called the <span class="it"><i>Vorono&#239; domain</i></span><indexg><index type="s" id="acch1o3index00033" significance="standard">Vorono&#239; domain</index></indexg> or <span class="it"><i>Dirichlet domain</i></span><indexg><index type="s" id="acch1o3index00034" significance="standard">Dirichlet domain</index></indexg> or <span class="it"><i>Wigner&#8211;Seitz cell</i></span><indexg><index type="s" id="acch1o3index00035" significance="standard">Wigner&#8211;Seitz cell</index></indexg> or <span class="it"><i>Wirkungsbereich</i></span><indexg><index id="acch1o3index00036" significance="standard" type="s"><span class="it"><i>Wirkungsbereich</i></span> (domain of influence)</index></indexg> or <span class="it"><i>first Brillouin zone</i></span><indexg><index type="s" id="acch1o3index00037" significance="standard">Brillouin zone</index></indexg> (for the case of reciprocal lattices in dual space, see Section 1.3.2.5<a href="/Ac/ch1o3v0001/#sec1o3o2o5"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
) of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> (around the origin).</p>
<p>The Vorono&#239; domain consists of those points of <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/> that are closer to the origin than to any other lattice point of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
</p>
<p>See Fig. 1.3.2.2<figr id="fig1o3o2o2" loc="float"/> for examples of these two types of unit cells in two-dimensional space.</p>
<figplace id="fig1o3o2o2"/>
</enun>
<p>
</p>
<p>It should be noted that the attribute `primitive' for a unit cell is often omitted. The term `unit cell' then either denotes a primitive unit cell in the sense of the definition above or a slight generalization of this, namely a cell spanned by vectors <span class="b"><b>a</b></span>, <span class="b"><b>b</b></span>, <span class="b"><b>c</b></span> which are not necessarily a lattice basis. This will be discussed in detail in the next section. If a unit cell in the even more general sense of a cell whose translates cover the whole space without overlap (thus including <span class="it"><i>e.g.</i></span> Vorono&#239; domains) is meant, this should be indicated by the context.</p>
<p>The construction of the Vorono&#239; domain is independent of the basis of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, as the Vorono&#239; domain is bounded by planes bisecting the line segment between the origin and a lattice point and perpendicular to this segment. In two-dimensional space, the Vorono&#239; domain is simply bounded by lines, in three-dimensional space it is bounded by planes and more generally it is bounded by (<span class="it"><i>n</i></span> &#8722; 1)-dimensional hyperplanes in <span class="it"><i>n</i></span>-dimensional space.</p>
<p>The boundaries of the Vorono&#239; domain and its translates overlap, thus in order to get a proper fundamental domain, part of the boundary has to be excluded from the Vorono&#239; domain.</p>
<p>The volume <span class="it"><i>V</i></span> of the unit cell can be expressed both <span class="it"><i>via</i></span> the metric tensor and <span class="it"><i>via</i></span> the cell parameters. One has <span class="fd"><a name="fdu1o3o2o11"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd18.svg" alt="[ \eqalign{V^2 &amp;= \det {\bi G} \cr&amp;= a^2 b^2 c^2 (1 - \cos^2 \alpha - \cos^2 \beta - \cos^2 \gamma + 2 \cos \alpha \cos \beta \cos \gamma) }]" class="mathimage" style="max-width: 100%; height: auto; width: 378px;"/></span>and thus <span class="fd"><a name="fdu1o3o2o12"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd19.svg" alt="[ V = a b c \sqrt{ 1 - \cos^2 \alpha - \cos^2 \beta - \cos^2 \gamma + 2 \cos \alpha \cos \beta \cos \gamma }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 362px;"/></span>Although the cell parameters depend on the chosen lattice basis, the volume of the unit cell is not affected by a transition to a different lattice basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>. As remarked in Section 1.3.2.1<secr id="sec1o3o2o1"/>, two lattice bases are related by an integral basis transformation <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> of determinant <img src="/teximages/acch1o3/acch1o3fi136.svg" alt="[\pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and therefore <img src="/teximages/acch1o3/acch1o3fi137.svg" alt="[\det {\bi G}' = \det ({\bi P}^{\rm T} \cdot {\bi G} \cdot {\bi P}) = \det {\bi G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;"/>, <span class="it"><i>i.e.</i></span> the determinant of the metric tensor is the same for all lattice bases.</p>
<p>Assuming that the vectors <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> form a <span class="it"><i>right-handed</i></span> system, the volume can also be obtained <span class="it"><i>via</i></span> <span class="fd"><a name="fdu1o3o2o13"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd20.svg" alt="[ V = {\bf a} \cdot ({\bf b} \times {\bf c}) = {\bf b} \cdot ({\bf c} \times {\bf a}) = {\bf c} \cdot ({\bf a} \times {\bf b}). ]" class="mathimage" style="max-width: 100%; height: auto; width: 246px;"/></span></p>
</div>

<div id="divsec1o3o2o4" class="sec2" secnum="1.3.2.4" fpage="24" lpage="27">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o2o4"><tree level="2"/></a>1.3.2.4. Primitive and centred lattices<indexg><index type="s" id="acch1o3index00038" significance="standard">centred lattice</index><index type="s" id="acch1o3index00039" significance="standard">primitive lattice</index><index id="acch1o3index00040" significance="standard" type="s">lattice<index type="s" significance="standard" id="acch1o3index00041">primitive</index></index><index significance="standard" id="acch1o3index00042" type="s">lattice<index id="acch1o3index00043" significance="standard" type="s">centred</index></index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o2o4.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o2o4" secnum="1.3.2.4">Primitive and centred lattices<indexg><index type="s" id="acch1o3index00038" significance="standard">centred lattice</index><index type="s" id="acch1o3index00039" significance="standard">primitive lattice</index><index id="acch1o3index00040" significance="standard" type="s">lattice<index type="s" significance="standard" id="acch1o3index00041">primitive</index></index><index significance="standard" id="acch1o3index00042" type="s">lattice<index id="acch1o3index00043" significance="standard" type="s">centred</index></index></indexg></st>
<p>The definition of a lattice as given in Section 1.3.2.1<secr id="sec1o3o2o1"/> states that a lattice consists precisely of the integral linear combinations of the vectors in a lattice basis. However, in crystallographic applications it has turned out to be convenient to work with bases that have particularly nice metric properties. For example, many calculations are simplified if the basis vectors are perpendicular to each other, <span class="it"><i>i.e.</i></span> if the metric tensor has all non-diagonal entries equal to zero. Moreover, it is preferable that the basis vectors reflect the symmetry properties of the lattice. By a case-by-case analysis of the different types of lattices a set of rules for convenient bases has been identified and bases conforming with these rules are called <span class="it"><i>conventional bases</i></span><indexg><index significance="standard" id="acch1o3index00044" type="s">conventional basis</index><index type="s" id="acch1o3index00045" significance="standard">basis<index type="s" significance="standard" id="acch1o3index00046">conventional</index></index></indexg>. The conventional bases are chosen such that in all cases the integral linear combinations of the basis vectors are lattice vectors, but it is admitted that not all lattice vectors are obtained as integral linear combinations.</p>
<p>To emphasize that a basis has the property that the vectors of a lattice are precisely the integral linear combinations of the basis vectors, such a basis is called a <span class="it"><i>primitive basis</i></span><indexg><index significance="standard" id="acch1o3index00047" type="s">primitive basis</index><index type="s" significance="standard" id="acch1o3index00048">basis<index id="acch1o3index00049" significance="standard" type="s">primitive</index></index></indexg> for this lattice.</p>
<p>If the conventional basis of a lattice is not a primitive basis for this lattice, the price to be paid for the transition to the conventional basis is that in addition to the integral linear combinations of the basis vectors one requires one or more <span class="it"><i>centring vectors</i></span><indexg><index type="s" id="acch1o3index00050" significance="standard">centring vector</index></indexg> in order to obtain all lattice vectors. These centring vectors have non-integral (but rational) coordinates with respect to the conventional basis. The name <span class="it"><i>centring</i></span> vectors reflects the fact that the additional vectors are usually the centres of the unit cell or of faces of the unit cell spanned by the conventional basis.</p>
<enun id="definition1o3o2o4o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o2o4" secnum="enun1.3.2.4">Definition</st>
<p>Let <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> be linearly independent vectors in <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/>.</p>
<div id="l1o3o2o4o1" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o2o4o1o1"/><p>(i) A lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is called a <span class="it"><i>primitive lattice</i></span> with respect to a basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> if <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> consists precisely of all integral linear combinations of <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, <span class="it"><i>i.e.</i></span> if <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> = <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> = <img src="/teximages/acch1o3/acch1o3fi147.svg" alt="[\{ l {\bf a} + m {\bf b} + n {\bf c} \mid l,m,n \in {\bb Z}\} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>.</p>
</li>
<li><a name="li1o3o2o4o1o2"/><p>(ii) A lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is called a <span class="it"><i>centred lattice</i></span> with respect to a basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> if the integral linear combinations <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> = <img src="/teximages/acch1o3/acch1o3fi151.svg" alt="[\{ l {\bf a} + m {\bf b} + n {\bf c} \mid l,m,n \in {\bb Z}\}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> form a proper sublattice of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> such that <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is the union of <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> with the translates of <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> by centring vectors <img src="/teximages/acch1o3/acch1o3fi156.svg" alt="[{\bf v}_1, \ldots, {\bf v}_s]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, <span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi157.svg" alt="[{\bf L} = {\bf L}_P \cup ({\bf v}_1 + {\bf L}_P)\ \cup]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> <img src="/teximages/acch1o3/acch1o3fi158.svg" alt="[ \ldots \cup ({\bf v}_s + {\bf L}_P) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>.</p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
Typically, the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is a conventional basis and in this case one often briefly says that a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is a <span class="it"><i>primitive lattice</i></span> or a <span class="it"><i>centred lattice</i></span> without explicitly mentioning the conventional basis.</p>
</enun>
<p>
</p>
<enun id="example1o3o2o4o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o2o4" secnum="enun1.3.2.4">Example</st>
<p>A rectangular lattice has as conventional basis a vector <img src="/teximages/abch15o2/abch15o2fi699.svg" alt="[{\bf a}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> of minimal length and a vector <img src="/teximages/abch15o2/abch15o2fi700.svg" alt="[{\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> of minimal length amongst the vectors perpendicular to <img src="/teximages/abch15o2/abch15o2fi699.svg" alt="[{\bf a}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>. The resulting primitive lattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is indicated by the filled nodes in Fig. 1.3.2.3<figr id="fig1o3o2o3" loc="float"/>. Now consider the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> having both the filled and the open nodes in Fig. 1.3.2.3<figr id="fig1o3o2o3" loc="float"/> as its lattice nodes. One sees that <img src="/teximages/acch1o3/acch1o3fi166.svg" alt="[{\bf a}' = \textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi167.svg" alt="[{\bf b}' = -\textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> is a primitive basis for <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, but it is more convenient to regard <img src="/teximages/acch1o3/acch1o3fi122.svg" alt="[{\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> as a centred lattice with respect to the basis <img src="/teximages/acch1o3/acch1o3fi54.svg" alt="[{\bf a}, {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with centring vector <img src="/teximages/acch1o3/acch1o3fi171.svg" alt="[{\bf v} = \textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>. The filled nodes then show the sublattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, the open nodes are the translate <img src="/teximages/acch1o3/acch1o3fi174.svg" alt="[{\bf v} + {\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is the union <img src="/teximages/acch1o3/acch1o3fi176.svg" alt="[{\bf L}_P \cup ({\bf v} + {\bf L}_P) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>.</p>
<figplace id="fig1o3o2o3"/>
</enun>
<p>
</p>
<p>Recalling that a lattice is in particular a group (with addition of vectors as operation), the sublattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> spanned by the basis of a centred lattice is a subgroup of the centred lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Together with the zero vector <img src="/teximages/acch1o3/acch1o3fi179.svg" alt="[{\bf v}_0 = {\bf 0}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>, the centring vectors form a set <img src="/teximages/acch1o3/acch1o3fi180.svg" alt="[{\bf v}_0, {\bf v}_1, \ldots, {\bf v}_s]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of coset representatives of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> relative to <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and the index [<span class="it"><i>i</i></span>] of <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> in <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is <span class="it"><i>s</i></span> + 1. In particular, the sum of two centring vectors is, up to a vector in <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, again a centring vector, <span class="it"><i>i.e.</i></span> for centring vectors <img src="/teximages/acch1o3/acch1o3fi186.svg" alt="[{\bf v}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/>, <img src="/teximages/acch1o3/acch1o3fi187.svg" alt="[{\bf v}_j]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.436913pt;"/> there is a unique centring vector <img src="/teximages/acch1o3/acch1o3fi188.svg" alt="[{\bf v}_k]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> (possibly <span class="b"><b>0</b></span>) such that <img src="/teximages/acch1o3/acch1o3fi189.svg" alt="[{\bf v}_i + {\bf v}_j = {\bf v}_k + {\bf w} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.436913pt;"/> for a vector <img src="/teximages/acch1o3/acch1o3fi190.svg" alt="[{\bf w} \in {\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>.</p>
<p>The concepts of primitive and centred lattices suggest corresponding notions of primitive and centred unit cells. If <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is a primitive basis for the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, then the parallelepiped spanned by <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is called a <span class="it"><i>primitive unit cell</i></span><indexg><index significance="standard" id="acch1o3index00051" type="s">primitive cell</index><index type="s" significance="standard" id="acch1o3index00052">unit cell<index type="s" significance="standard" id="acch1o3index00053">primitive</index></index></indexg> (or primitive cell<indexg><index significance="standard" id="acch1o3index00054" type="s">primitive cell</index><index significance="standard" id="acch1o3index00055" type="s">cell<index type="s" significance="standard" id="acch1o3index00056">primitive</index></index></indexg>); if <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> spans a proper sublattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> of index [<span class="it"><i>i</i></span>] in <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, then the parall&#173;el&#173;epiped spanned by <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is called a <span class="it"><i>centred unit cell</i></span><indexg><index type="s" significance="standard" id="acch1o3index00057">unit cell<index significance="standard" id="acch1o3index00058" type="s">centred</index></index></indexg> (or centred cell<indexg><index id="acch1o3index00059" significance="standard" type="s">centred cell</index><index type="s" id="acch1o3index00060" significance="standard">cell<index significance="standard" id="acch1o3index00061" type="s">centred</index></index></indexg>). Since translating a centred cell by translations from the sublattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> covers the full space, the centred cell contains one representative from each coset of the centred lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> relative to <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>. This means that the centred cell contains [<span class="it"><i>i</i></span>] lattice vectors of the centred lattice and due to this a centred cell is also called a <span class="it"><i>multiple cell</i></span><indexg><index id="acch1o3index00062" significance="standard" type="s">multiple cell</index><index id="acch1o3index00063" significance="standard" type="s">cell<index id="acch1o3index00064" significance="standard" type="s">multiple</index></index></indexg>. As a consequence, the volume of the centred cell is [<span class="it"><i>i</i></span>] times as large as that of a primitive cell for <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
<p>For a conventional basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, the parallel&#173;epiped spanned by <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is called a <span class="it"><i>conventional unit cell</i></span><indexg><index type="s" id="acch1o3index00065" significance="standard">conventional cell</index><index type="s" id="acch1o3index00066" significance="standard">cell<index type="s" significance="standard" id="acch1o3index00067">conventional</index></index><index id="acch1o3index00068" significance="standard" type="s">unit cell<index significance="standard" id="acch1o3index00069" type="s">conventional</index></index></indexg> (or conventional cell<indexg><index type="s" significance="standard" id="acch1o3index00070">conventional cell</index><index id="acch1o3index00071" significance="standard" type="s">cell<index type="s" significance="standard" id="acch1o3index00072">conventional</index></index></indexg>) of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Depending on whether the conventional basis is a primitive basis or not, <span class="it"><i>i.e.</i></span> whether the lattice is primitive or centred, the conventional cell is a primitive or a centred cell.</p>
<p><span class="it"><i>Remark</i></span>: It is important to note that the cell parameters given in the description of a crystallographic structure almost always refer to a conventional cell. When in the crystallographic literature the term `unit cell' is used without further attributes, in most cases a conventional unit cell (as specified by the cell parameters) is meant, which is a primitive or centred (multiple) cell depending on whether the lattice is primitive or centred.</p>
<enun id="example1o3o2o4o3" type="LONG">

<h4 class="enunlong"><i>Example (continued)</i></h4>
<st enunid="enunsec1o3o2o4" secnum="enun1.3.2.4">Example (continued)</st>
<p>In the example of a centred rectangular lattice, the conventional basis <img src="/teximages/abch15o2/abch15o2fi1476.svg" alt="[{\bf a}, {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> spans the centred unit cell indicated by solid lines in Fig. 1.3.2.4<figr id="fig1o3o2o4" loc="float"/>, whereas the primitive basis <img src="/teximages/acch1o3/acch1o3fi166.svg" alt="[{\bf a}' = \textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi167.svg" alt="[{\bf b}' = -\textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> spans the primitive unit cell indicated by dashed lines. One observes that the centred cell contains two lattice vectors, <img src="/teximages/acch1o3/acch1o3fi209.svg" alt="[{\bf o}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> and <img src="/teximages/acch1o3/acch1o3fi210.svg" alt="[{\bf a'} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>, whereas the primitive cell only contains the zero vector <img src="/teximages/acch1o3/acch1o3fi211.svg" alt="[{\bf o} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> (note that due to the condition <img src="/teximages/acch1o3/acch1o3fi212.svg" alt="[0 \leq x,y \,\lt\, 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> for the points in the unit cell the other vertices <img src="/teximages/acch1o3/acch1o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of the cell are excluded). The volume of the centred cell is clearly twice as large as that of the primitive cell.</p>
<figplace id="fig1o3o2o4"/>
</enun>
<p>
</p>
<p>Figures displaying the different primitive and centred unit cells as well as tables describing the metric properties of the different primitive and centred lattices are given in <related volume="A" revision="c" chnum="3.1" url="/Ac/ch3o1v0001/#sec3o1o2"><relchtitle>Crystal lattices</relchtitle><relau>H. Burzlaff</relau><relau>H. Grimmer</relau><relau>B. Gruber</relau><relau>P. M. de Wolff</relau><relau>H. Zimmermann</relau></related>Section 3.1.2<a href="/Ac/ch3o1v0001/#sec3o1o2"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
.</p>
<p/>
<enun id="example1o3o2o4o4" type="LONG">

<h4 class="enunlong"><i>Examples</i></h4>
<st enunid="enunsec1o3o2o4" secnum="enun1.3.2.4">Examples</st>
<p/>
<div id="l1o3o2o4o2" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o2o4o2o1"/><p>(i) The conventional basis for a <span class="it"><i>primitive cubic lattice</i></span> (<span class="it"><i>cP</i></span>) is a basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of vectors of equal length which are pairwise perpendicular, <span class="it"><i>i.e.</i></span> with <img src="/teximages/acch1o3/acch1o3fi215.svg" alt="[|{\bf a}| = |{\bf b}| = |{\bf c}|]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> and <img src="/teximages/acch1o3/acch1o3fi216.svg" alt="[{\bf a} \cdot {\bf b} = {\bf b} \cdot {\bf c} = {\bf c} \cdot {\bf a} = 0 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>. As the name indicates, this basis is a primitive basis.</p>
</li>
<li><a name="li1o3o2o4o2o2"/><p>(ii) A <span class="it"><i>body-centred cubic lattice</i></span> (<span class="it"><i>cI</i></span>) has as its conventional basis the conventional basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of a primitive cubic lattice, but the lattice also contains the centring vector <img src="/teximages/acch1o3/acch1o3fi218.svg" alt="[{\bf v} = \textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b} + \textstyle{{1}\over{2}} {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> which points to the centre of the conventional cell. If we denote the primitive cubic lattice by <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, then the body-centred cubic lattice <img src="/teximages/acch1o3/acch1o3fi220.svg" alt="[{\bf L}_I]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is the union of <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and the translate <img src="/teximages/acch1o3/acch1o3fi222.svg" alt="[{\bf v} + {\bf L}_P = \{ {\bf v} + {\bf w} \mid {\bf w} \in {\bf L}_P \}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>. Since <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is a sublattice of index 2 in <img src="/teximages/acch1o3/acch1o3fi224.svg" alt="[{\bf L}_I ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, the ratio of the volumes of the centred and the primitive cell of the body-centred cubic lattice is 2.</p>
<p>A possible primitive basis for <img src="/teximages/acch1o3/acch1o3fi220.svg" alt="[{\bf L}_I]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is <img src="/teximages/abch2o2/abch2o2fi362.svg" alt="[{\bf a}' = {\bf a}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>, <img src="/teximages/acch1o3/acch1o3fi227.svg" alt="[{\bf b}' = {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>, <img src="/teximages/acch1o3/acch1o3fi228.svg" alt="[{\bf c}' = \textstyle{{1}\over{2}} ({\bf a} + {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>. With respect to this basis, the metric tensor of <img src="/teximages/acch1o3/acch1o3fi220.svg" alt="[{\bf L}_I]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is<span class="fd"><a name="fdu111"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd21.svg" alt="[a^2 \cdot \pmatrix{ 1 &amp; 0 &amp; \textstyle{{1}\over{2}} \cr 0 &amp; 1 &amp; \textstyle{{1}\over{2}} \cr \textstyle{{1}\over{2}} &amp; \textstyle{{1}\over{2}} &amp; \textstyle{{3}\over{4}} } ]" class="mathimage" style="max-width: 100%; height: auto; width: 102px;"/></span>(where <img src="/teximages/acch1o3/acch1o3fi230.svg" alt="[a = {\bf a} \cdot {\bf a}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>). However, it is more common to use a primitive basis with vectors of the same length and equal interaxial angles. Such a basis is <img src="/teximages/acch1o3/acch1o3fi231.svg" alt="[{\bf a}'' = \textstyle{{1}\over{2}} (-{\bf a} + {\bf b} + {\bf c}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi232.svg" alt="[{\bf b}'' = \textstyle{{1}\over{2}} ({\bf a} - {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi233.svg" alt="[{\bf c}'' = \textstyle{{1}\over{2}} ({\bf a} + {\bf b} - {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> (<span class="it"><i>cf.</i></span> <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#fig1o5o1o3"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>Fig. 1.5.1.3<a href="/Ac/ch1o5v0001/#fig1o5o1o3"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
), and with respect to this basis the metric tensor of <img src="/teximages/acch1o3/acch1o3fi220.svg" alt="[{\bf L}_I]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is<span class="fd"><a name="fdu12"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd22.svg" alt="[{{a^2}\over{4}} \cdot \pmatrix{ 3 &amp; -1 &amp; -1 \cr -1 &amp; 3 &amp; -1 \cr -1 &amp; -1 &amp; 3 } .]" class="mathimage" style="max-width: 100%; height: auto; width: 145px;"/></span></p>
</li>
<li><a name="li1o3o2o4o2o3"/><p>(iii) The conventional basis for a <span class="it"><i>face-centred cubic lattice</i></span> (<img src="/teximages/acch1o3/acch1o3fi235.svg" alt="[cF]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.131015999999995pt;"/>) is again the conventional basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of a primitive cubic lattice, but the lattice also contains the three centring vectors <img src="/teximages/acch1o3/acch1o3fi237.svg" alt="[{\bf v}_1 = \textstyle{{1}\over{2}} {\bf b} + \textstyle{{1}\over{2}} {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi238.svg" alt="[{\bf v}_2 = \textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi239.svg" alt="[{\bf v}_3 = \textstyle{{1}\over{2}} {\bf a} + \textstyle{{1}\over{2}} {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> which point to the centres of faces of the conventional cell.</p>
<p>The face-centred cubic lattice <img src="/teximages/acch1o3/acch1o3fi240.svg" alt="[{\bf L}_F]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is the union of the primitive cubic lattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> with its translates <img src="/teximages/acch1o3/acch1o3fi242.svg" alt="[{\bf v}_i + {\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> by the three centring vectors. The ratio of the volumes of the centred and the primitive cell of the face-centred cubic lattice is 4. In this case, the centring vectors actually form a primitive basis of <img src="/teximages/acch1o3/acch1o3fi240.svg" alt="[{\bf L}_F]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>. With respect to the basis <img src="/teximages/acch1o3/acch1o3fi244.svg" alt="[{\bf a}' = \textstyle{{1}\over{2}} ({\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi245.svg" alt="[{\bf b}' = \textstyle{{1}\over{2}} ({\bf a} + {\bf c}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi246.svg" alt="[{\bf c}' = \textstyle{{1}\over{2}} ({\bf a} + {\bf b})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> (<span class="it"><i>cf.</i></span> <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#fig1o5o1o4"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>Fig. 1.5.1.4<a href="/Ac/ch1o5v0001/#fig1o5o1o4"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
) the metric tensor of <img src="/teximages/acch1o3/acch1o3fi240.svg" alt="[{\bf L}_F]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is<span class="fd"><a name="fdu13"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd23.svg" alt="[{{a^2}\over{4}} \cdot \pmatrix{ 2 &amp; 1 &amp; 1 \cr 1 &amp; 2 &amp; 1 \cr 1 &amp; 1 &amp; 2 } .]" class="mathimage" style="max-width: 100%; height: auto; width: 110px;"/></span></p>
</li>
<li><a name="li1o3o2o4o2o4"/><p>(iv) In the conventional basis of a primitive hexagonal lattice, the basis vector <span class="b"><b>c</b></span> is chosen as a shortest vector along a sixfold axis. The vectors <span class="b"><b>a</b></span> and <span class="b"><b>b</b></span> then are shortest vectors along twofold axes in a plane perpendicular to <span class="b"><b>c</b></span> and such that they enclose an angle of 120&#176;. The corresponding metric tensor has the form<span class="fd"><a name="fdu14"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd24.svg" alt="[\let\normalbaselines\relax\openup1pt\pmatrix{ a^2 &amp; -\displaystyle{{a^2}\over{2}} &amp; 0 \cr -\displaystyle{{a^2}\over{2}} &amp; a^2 &amp; 0 \cr 0 &amp; 0 &amp; c^2 } .]" class="mathimage" style="max-width: 100%; height: auto; width: 126px;"/></span></p>
</li>
<li><a name="li1o3o2o4o2o5"/><p>(v) In the unit cell of the primitive hexagonal lattice <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, a point with coordinates <img src="/teximages/acch1o3/acch1o3fi249.svg" alt="[\textstyle{{2}\over{3}}, \textstyle{{1}\over{3}}, z ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> is mapped to the points <img src="/teximages/acch1o3/acch1o3fi250.svg" alt="[-\textstyle{{1}\over{3}}, \textstyle{{1}\over{3}}, z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> and <img src="/teximages/acch1o3/acch1o3fi251.svg" alt="[-\textstyle{{1}\over{3}}, -\textstyle{{2}\over{3}}, z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> under the threefold rotation around the <span class="it"><i>c</i></span> axis. Both of these points are translates of <img src="/teximages/acch1o3/acch1o3fi252.svg" alt="[\textstyle{{2}\over{3}}, \textstyle{{1}\over{3}}, z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> by lattice vectors of <img src="/teximages/acch1o3/acch1o3fi253.svg" alt="[{\bf L}_P ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>. This means that a centring vector of the form <img src="/teximages/acch1o3/acch1o3fi254.svg" alt="[\textstyle{{2}\over{3}} {\bf a} + \textstyle{{1}\over{3}} {\bf b} + z {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> will result in a lattice which is invariant under the threefold rotation. Choosing <img src="/teximages/acch1o3/acch1o3fi255.svg" alt="[{\bf v}_1 = \textstyle{{1}\over{3}} (2 {\bf a} + {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> as centring vector, the lattice generated by <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi257.svg" alt="[{\bf v}_1 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> contains <img src="/teximages/acch1o3/acch1o3fi146.svg" alt="[{\bf L}_P]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> as a sublattice of index 3 with coset representatives <img src="/teximages/acch1o3/acch1o3fi259.svg" alt="[{\bf 0}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154837000000001pt;"/>, <img src="/teximages/acch1o3/acch1o3fi260.svg" alt="[{\bf v}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi261.svg" alt="[2 {\bf v}_1 = \textstyle{{1}\over{3}} (4 {\bf a} + 2 {\bf b} + 2 {\bf c}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>. The coset representative <img src="/teximages/acch1o3/acch1o3fi262.svg" alt="[2 {\bf v}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is commonly replaced by <img src="/teximages/acch1o3/acch1o3fi263.svg" alt="[{\bf v}_2 = \textstyle{{1}\over{3}} ({\bf a} + 2 {\bf b} + 2 {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/> and the centred lattice <img src="/teximages/acch1o3/acch1o3fi264.svg" alt="[{\bf L}_R]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> with centring vectors <img src="/teximages/acch1o3/acch1o3fi260.svg" alt="[{\bf v}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi266.svg" alt="[{\bf v}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> so obtained is called the <span class="it"><i>rhombohedrally centred lattice</i></span><indexg><index id="acch1o3index00073" significance="standard" type="s">rhombohedral lattice</index><index id="acch1o3index00074" significance="standard" type="s">lattice<index type="s" id="acch1o3index00075" significance="standard">rhombohedral</index></index></indexg> (<span class="it"><i>hR</i></span>). The ratio of the volumes of the centred and the primitive cell of the rhombohedrally centred lattice is 3.</p>
<p>For this lattice, the primitive basis of <img src="/teximages/acch1o3/acch1o3fi264.svg" alt="[{\bf L}_R]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> consisting of three shortest non-coplanar vectors which are permuted by the threefold rotation is also regarded as a conventional basis. With respect to the above lattice basis of the primitive hexagonal lattice, this basis can be chosen as <img src="/teximages/acch1o3/acch1o3fi268.svg" alt="[{\bf a}' = \textstyle{{1}\over{3}} (2 {\bf a} + {\bf b} + {\bf c}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>, <img src="/teximages/acch1o3/acch1o3fi269.svg" alt="[{\bf b}' = \textstyle{{1}\over{3}} (-{\bf a} + {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>, <img src="/teximages/acch1o3/acch1o3fi270.svg" alt="[{\bf c}' = \textstyle{{1}\over{3}} (-{\bf a} - 2 {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>. The metric tensor with respect to this basis is<span class="fd"><a name="fdu15"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd25.svg" alt="[\let\normalbaselines\relax\openup1pt{{1}\over{9}} \cdot \displaystyle\pmatrix{ 3 a^2 + c^2 &amp; -\displaystyle{{3}\over{2}} a^2 + c^2 &amp; -\displaystyle{{3}\over{2}} a^2 + c^2 \cr -\displaystyle{{3}\over{2}} a^2 + c^2 &amp; 3 a^2 + c^2 &amp; -\displaystyle{{3}\over{2}} a^2 + c^2 \cr -\displaystyle{{3}\over{2}} a^2 + c^2 &amp; -\displaystyle{{3}\over{2}} a^2 + c^2 &amp; 3 a^2 + c^2 }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 269px;"/></span></p>
<p>Details about the transformations between hexagonal and rhombohedral lattices are given in Section <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#sec1o5o3o1"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>1.5.3.1<a href="/Ac/ch1o5v0001/#sec1o5o3o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 and <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#table1o5o1o1"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>Table 1.5.1.1<a href="/Ac/ch1o5v0001/#table1o5o1o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 (see also <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#fig1o5o1o6"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>Fig. 1.5.1.6<a href="/Ac/ch1o5v0001/#fig1o5o1o6"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
).</p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
</p>
</enun>
<p>
</p>
<p><span class="it"><i>Remark</i></span>: In three-dimensional space <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/>, the conventional bases have been chosen in such a way that any isometry of a centred lattice maps the sublattice generated by the conventional basis to itself. This means that the matrices of the isometries of the lattice are not only integral with respect to a primitive basis, but also when written with respect to the conventional basis. The advantage of the conventional basis is that the matrices are much simpler.</p>
<p>In dimensions <img src="/teximages/acch1o3/acch1o3fi272.svg" alt="[n \geq 4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.637859pt;"/>, such a choice of a conventional basis is in general no longer possible. For example, one will certainly regard the standard orthonormal basis<span class="fd"><a name="fdu16"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd26.svg" alt="[{\bf a} = \pmatrix{ 1 \cr 0 \cr 0 \cr 0 }\quad {\bf b} = \pmatrix{ 0 \cr 1 \cr 0 \cr 0 }\quad {\bf c} = \pmatrix{ 0 \cr 0 \cr 1 \cr 0 } \quad {\bf d} = \pmatrix{ 0 \cr 0 \cr 0 \cr 1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 284px;"/></span>of the four-dimensional hypercubic lattice as a conventional basis. The body-centred lattice with centring vector <img src="/teximages/acch1o3/acch1o3fi273.svg" alt="[\textstyle{{1}\over{2}} ({\bf a} + {\bf b} + {\bf c} + {\bf d}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> is invariant under all the isometries of the hypercubic lattice, but the body-centred lattice itself allows isometries that do not leave the hypercubic lattice invariant. Thus, not all isometries of the body-centred lattice are integral with respect to the conventional basis of the hypercubic lattice.</p>
</div>

<div id="divsec1o3o2o5" class="sec2" secnum="1.3.2.5" fpage="27" lpage="28">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o2o5"><tree level="2"/></a>1.3.2.5. Reciprocal lattice<indexg><index significance="standard" id="acch1o3index00076" type="s">reciprocal lattice</index><index significance="standard" id="acch1o3index00077" type="s">lattice<index significance="standard" id="acch1o3index00078" type="s">reciprocal</index></index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o2o5.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o2o5" secnum="1.3.2.5">Reciprocal lattice<indexg><index significance="standard" id="acch1o3index00076" type="s">reciprocal lattice</index><index significance="standard" id="acch1o3index00077" type="s">lattice<index significance="standard" id="acch1o3index00078" type="s">reciprocal</index></index></indexg></st>
<p>For crystallographic applications, a lattice <img src="/teximages/acch1o3/acch1o3fi274.svg" alt="[{\bf L}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> related to <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is of utmost importance. If the atoms are placed at the nodes of a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, then the diffraction pattern will have sharp Bragg peaks at the nodes of the <span class="it"><i>reciprocal lattice</i></span> <img src="/teximages/acch1o3/acch1o3fi277.svg" alt="[{\bf L}^* ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. More generally, if the crystal pattern is invariant under translations from <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, then the locations of the Bragg peaks in the diffraction pattern will be invariant under translations from <img src="/teximages/acch1o3/acch1o3fi274.svg" alt="[{\bf L}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
<enun id="definition1o3o2o5o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o2o5" secnum="enun1.3.2.5">Definition</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi280.svg" alt="[{\bf L} \subset {\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478207000000001pt;"/> be a lattice with lattice basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>. Then the <span class="it"><i>reciprocal basis</i></span><indexg><index type="s" significance="standard" id="acch1o3index00079">reciprocal basis</index><index id="acch1o3index00080" significance="standard" type="s">basis<index type="s" id="acch1o3index00081" significance="standard">reciprocal</index></index></indexg> <img src="/teximages/acch1o3/acch1o3fi282.svg" alt="[{\bf a}^*, {\bf b}^*, {\bf c}^* ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is defined by the properties <span class="fd"><a name="fdu1o3o2o14"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd27.svg" alt="[{\bf a} \cdot {\bf a}^* = {\bf b} \cdot {\bf b}^* = {\bf c} \cdot {\bf c}^* = 1]" class="mathimage" style="max-width: 100%; height: auto; width: 151px;"/></span>and<span class="fd"><a name="fdu17"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd28.svg" alt="[{\bf b} \cdot {\bf a}^* = {\bf c} \cdot {\bf a}^* = {\bf c} \cdot {\bf b}^* = {\bf a} \cdot {\bf b}^* = {\bf a} \cdot {\bf c}^* = {\bf b} \cdot {\bf c}^* = 0 , ]" class="mathimage" style="max-width: 100%; height: auto; width: 301px;"/></span>which can conveniently be written as the matrix equation <span class="fd"><a name="fdu1o3o2o15"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd29.svg" alt="[ \pmatrix{ {\bf a} \cdot {\bf a}^* &amp; {\bf a} \cdot {\bf b}^* &amp; {\bf a} \cdot {\bf c}^* \cr {\bf b} \cdot {\bf a}^* &amp; {\bf b} \cdot {\bf b}^* &amp; {\bf b} \cdot {\bf c}^* \cr {\bf c} \cdot {\bf a}^* &amp; {\bf c} \cdot {\bf b}^* &amp; {\bf c} \cdot {\bf c}^* } = \pmatrix{ 1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } = {\bi I}_3. ]" class="mathimage" style="max-width: 100%; height: auto; width: 278px;"/></span></p>
<p>This means that <img src="/teximages/acch1o3/acch1o3fi283.svg" alt="[{\bf a}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> is perpendicular to the plane spanned by <img src="/teximages/abch15o2/abch15o2fi700.svg" alt="[{\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> and <img src="/teximages/acch1o3/acch1o3fi285.svg" alt="[{\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> and its projection to the line along <img src="/teximages/abch15o2/abch15o2fi699.svg" alt="[{\bf a}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> has length <img src="/teximages/acch1o3/acch1o3fi287.svg" alt="[1/|{\bf a}|]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>. Analogous properties hold for <img src="/teximages/acch1o3/acch1o3fi288.svg" alt="[{\bf b}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> and <img src="/teximages/acch1o3/acch1o3fi289.svg" alt="[{\bf c}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>.</p>
<p>The <span class="it"><i>reciprocal lattice</i></span> <img src="/teximages/acch1o3/acch1o3fi274.svg" alt="[{\bf L}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is defined to be the lattice with lattice basis <img src="/teximages/acch1o3/acch1o3fi282.svg" alt="[{\bf a}^*, {\bf b}^*, {\bf c}^* ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
</enun>
<p>
</p>
<p>In three-dimensional space <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/>, the reciprocal basis can be determined <span class="it"><i>via</i></span> the vector product. Assuming that <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> form a right-handed system that spans a unit cell of volume <span class="it"><i>V</i></span>, the relation <img src="/teximages/acch1o3/acch1o3fi295.svg" alt="[{\bf a} \cdot ({\bf b} \times {\bf c}) = V]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> and the defining conditions <img src="/teximages/acch1o3/acch1o3fi296.svg" alt="[{\bf a} \cdot {\bf a}^* = 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o3/acch1o3fi297.svg" alt="[{\bf b} \cdot {\bf a}^* = {\bf c} \cdot {\bf a}^* = 0 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> imply that <img src="/teximages/acch1o3/acch1o3fi298.svg" alt="[{\bf a}^* = \textstyle{{1}\over{V}} ({\bf b} \times {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.265543pt;"/>. Analogously, one has <img src="/teximages/acch1o3/acch1o3fi299.svg" alt="[{\bf b}^* = \textstyle{{1}\over{V}} ({\bf c} \times {\bf a}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.265543pt;"/> and <img src="/teximages/acch1o3/acch1o3fi300.svg" alt="[{\bf c}^* = \textstyle{{1}\over{V}} ({\bf a} \times {\bf b})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.265543pt;"/>.</p>
<p>The reciprocal lattice can also be defined independently of a lattice basis by stating that the vectors of the reciprocal lattice have integral scalar products with all vectors of the lattice: <span class="fd"><a name="fdu1o3o2o16"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd30.svg" alt="[ {\bf L}^* = \{ {\bf w}^* \in {\bb V}^3 \mid {\bf v} \cdot {\bf w}^* \in {\bb Z}\ {\rm for\ all }\ {\bf v} \in {\bf L} \}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 257px;"/></span></p>
<p>Owing to the symmetry <img src="/teximages/acch1o3/acch1o3fi301.svg" alt="[{\bf v} \cdot {\bf w} = {\bf w} \cdot {\bf v}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> of the scalar product, the roles of the basis and its reciprocal basis can be interchanged. This means that <img src="/teximages/acch1o3/acch1o3fi302.svg" alt="[({\bf L}^*)^* = {\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>, <span class="it"><i>i.e.</i></span> taking the reciprocal lattice <img src="/teximages/acch1o3/acch1o3fi303.svg" alt="[({\bf L}^*)^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> of the reciprocal lattice <img src="/teximages/acch1o3/acch1o3fi274.svg" alt="[{\bf L}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> results in the original lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> again.</p>
<p><span class="it"><i>Remark</i></span>: In parts of the literature, especially in physics, the reciprocal lattice is defined slightly differently. The condition there is that <img src="/teximages/acch1o3/acch1o3fi306.svg" alt="[{\bf a}_i \cdot {\bf a}^*_j = 2 \pi]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.599165pt;"/> if <img src="/teximages/acch1o3/acch1o3fi307.svg" alt="[i = j]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.465475pt;"/> and 0 otherwise and thus the reciprocal lattice is scaled by the factor 2&#960; as compared to the above definition. By this variation the exponential function <img src="/teximages/acch1o3/acch1o3fi308.svg" alt="[\exp(-2\pi i \, {\bf v} \cdot {\bf w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.58458pt;"/> is changed to <img src="/teximages/acch1o3/acch1o3fi309.svg" alt="[\exp(-i \, {\bf v} \cdot {\bf w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.58458pt;"/>, which simplifies the formulas for the Fourier transform.</p>
<enun id="example1o3o2o5o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o2o5" secnum="enun1.3.2.5">Example</st>
<p>Let <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> be the lattice basis of a primitive cubic lattice. Then the body-centred cubic lattice <img src="/teximages/acch1o3/acch1o3fi220.svg" alt="[{\bf L}_I]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> with centring vector <img src="/teximages/acch1o3/acch1o3fi312.svg" alt="[\textstyle{{1}\over{2}} ({\bf a} + {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> is the reciprocal lattice of the rescaled face-centred cubic lattice <img src="/teximages/acch1o3/acch1o3fi313.svg" alt="[2 {\bf L}_F ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <span class="it"><i>i.e.</i></span> the lattice spanned by <img src="/teximages/acch1o3/acch1o3fi314.svg" alt="[2 {\bf a}, 2 {\bf b}, 2 {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> and the centring vectors <img src="/teximages/acch1o3/acch1o3fi315.svg" alt="[{\bf b} + {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o3/acch1o3fi316.svg" alt="[{\bf a} + {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o1/acch1o1fi19.svg" alt="[{\bf a} + {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>.</p>
</enun>
<p>
</p>
<p>This example illustrates that a lattice and its reciprocal lattice need not have the same type. The reciprocal lattice of a body-centred cubic lattice is a face-centred cubic lattice and <span class="it"><i>vice versa</i></span>. However, the conventional bases are chosen such that for a primitive lattice with a conventional basis as lattice basis, the reciprocal lattice is a primitive lattice of the same type. Therefore the reciprocal lattice of a centred lattice is always a centred lattice for the same type of primitive lattice.</p>
<p>The reciprocal basis can be read off the inverse matrix of the metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/>: We denote by <img src="/teximages/acch1o3/acch1o3fi319.svg" alt="[{\bi P}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> the matrix containing the coordinate columns of <img src="/teximages/acch1o3/acch1o3fi320.svg" alt="[{\bf a}^*, {\bf b}^*, {\bf c}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with respect to the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, so that <img src="/teximages/acch1o3/acch1o3fi322.svg" alt="[{\bf a}^* = P^*_{11} {\bf a} + P^*_{21} {\bf b} + P^*_{31} {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.066681pt;"/> <span class="it"><i>etc</i></span>. Recalling that scalar products can be computed by multiplying the metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> from the left and right with coordinate columns with respect to the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, the conditions<span class="fd"><a name="fdu18"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd31.svg" alt="[\pmatrix{ {\bf a} \cdot {\bf a}^* &amp; {\bf a} \cdot {\bf b}^* &amp; {\bf a} \cdot {\bf c}^* \cr {\bf b} \cdot {\bf a}^* &amp; {\bf b} \cdot {\bf b}^* &amp; {\bf b} \cdot {\bf c}^* \cr {\bf c} \cdot {\bf a}^* &amp; {\bf c} \cdot {\bf b}^* &amp; {\bf c} \cdot {\bf c}^* } = {\bi I}_3]" class="mathimage" style="max-width: 100%; height: auto; width: 179px;"/></span>defining the reciprocal basis result in the matrix equation <img src="/teximages/acch1o3/acch1o3fi325.svg" alt="[{\bi I}_3 \cdot {\bi G} \cdot {\bi P}^* = {\bi I}_3 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>, since the coordinate columns of the basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with respect to itself are the rows of the identity matrix <img src="/teximages/acch1o3/acch1o3fi327.svg" alt="[{\bi I}_3 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>, and <img src="/teximages/acch1o3/acch1o3fi319.svg" alt="[{\bi P}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> was just defined to contain the coordinate columns of <img src="/teximages/acch1o3/acch1o3fi320.svg" alt="[{\bf a}^*, {\bf b}^*, {\bf c}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>. But <img src="/teximages/acch1o3/acch1o3fi330.svg" alt="[{\bi G} \cdot {\bi P}^* = {\bi I}_3 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/> means that <img src="/teximages/acch1o3/acch1o3fi331.svg" alt="[{\bi P}^* = {\bi G}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214390000000002pt;"/> and thus the coordinate columns of <img src="/teximages/acch1o3/acch1o3fi320.svg" alt="[{\bf a}^*, {\bf b}^*, {\bf c}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with respect to the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> are precisely the columns of the inverse matrix <img src="/teximages/acch1o3/acch1o3fi334.svg" alt="[{\bi G}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214390000000002pt;"/> of the metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/>.</p>
<p>From <img src="/teximages/acch1o3/acch1o3fi331.svg" alt="[{\bi P}^* = {\bi G}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214390000000002pt;"/> one also derives that the metric tensor <img src="/teximages/acch1o3/acch1o3fi337.svg" alt="[{\bi G}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> of the reciprocal basis is <span class="fd"><a name="fdu1o3o2o17"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd32.svg" alt="[ {\bi G}^* = {{\bi P}^*}^{\rm T} \cdot {\bi G} \cdot {\bi P}^* = {\bi G}^{-1} \cdot {\bi G} \cdot {\bi G}^{-1} = {\bi G}^{-1}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 245px;"/></span>This means that the metric tensors of a basis and its reciprocal basis are inverse matrices of each other. As a further consequence, the volume <img src="/teximages/acch1o3/acch1o3fi338.svg" alt="[V^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/> of the unit cell spanned by the reciprocal basis is <img src="/teximages/acch1o3/acch1o3fi339.svg" alt="[V^* = V^{-1} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214390000000002pt;"/>, <span class="it"><i>i.e.</i></span> the inverse of the volume of the unit cell spanned by <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
<p>Of course, the reciprocal basis can also be computed from the vectors <img src="/teximages/acch1o3/acch1o3fi341.svg" alt="[{\bf a}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> directly. If <img src="/teximages/acch1o1/acch1o1fi146.svg" alt="[{\bi B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and <img src="/teximages/acch1o3/acch1o3fi343.svg" alt="[{\bi B}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> are the matrices containing as <span class="it"><i>i</i></span>th column the vectors <img src="/teximages/acch1o3/acch1o3fi341.svg" alt="[{\bf a}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> and <img src="/teximages/acch1o3/acch1o3fi345.svg" alt="[{\bf a}^*_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.04286pt;"/>, respectively, then the relation defining the reciprocal basis reads as <img src="/teximages/acch1o3/acch1o3fi346.svg" alt="[{\bi B}^{\rm T} \cdot {\bi B}^* = {\bi I}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>, <span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi347.svg" alt="[{\bi B}^* = ({\bi B}^{-1})^{\rm T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>. Thus, the reciprocal basis vector <img src="/teximages/acch1o3/acch1o3fi345.svg" alt="[{\bf a}^*_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.04286pt;"/> is the <span class="it"><i>i</i></span>th column of the transposed matrix of <img src="/teximages/acch1o3/acch1o3fi349.svg" alt="[{\bi B}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.00000000102796e-06pt;"/> and thus the <span class="it"><i>i</i></span>th <span class="it"><i>row</i></span> of the inverse of the matrix <img src="/teximages/acch1o1/acch1o1fi146.svg" alt="[{\bi B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> containing the <img src="/teximages/acch1o3/acch1o3fi341.svg" alt="[{\bf a}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> as columns.</p>
<p>The relations between the parameters of the unit cell spanned by the reciprocal basis vectors and those of the unit cell spanned by the original basis can either be obtained from the vector product expressions for <img src="/teximages/acch1o3/acch1o3fi283.svg" alt="[{\bf a}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o3/acch1o3fi288.svg" alt="[{\bf b}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o3/acch1o3fi289.svg" alt="[{\bf c}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> or by explicitly inverting the metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> (<span class="it"><i>e.g.</i></span> using Cramer's rule). The latter approach would also be applicable in <span class="it"><i>n</i></span>-dimensional space. Either way, one finds <span class="fd"><a name="fdu1o3o2o18"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd33.svg" alt="[ \displaylines{a^* = {{bc \sin \alpha}\over{V}}, \quad b^* = {{ca \sin \beta}\over{V}},\quad c^* = {{ab \sin \gamma}\over{V}},\cr \sin \alpha^* = {{V}\over{abc \sin \beta \sin \gamma}},\quad \cos \alpha^* = {{\cos \beta \cos \gamma - \cos \alpha}\over{\sin \beta \sin \gamma}}, \cr \sin \beta^* = {{V}\over{abc \sin \gamma \sin \alpha}},\quad \cos \beta^* = {{\cos \gamma \cos \alpha - \cos \beta}\over{\sin \gamma \sin \alpha}}, \cr \sin \gamma^* = {{V}\over{abc \sin \alpha \sin \beta}}, \quad \cos \gamma^* = {{\cos \alpha \cos \beta - \cos \gamma}\over{\sin \alpha \sin \beta}}. }]" class="mathimage" style="max-width: 100%; height: auto; width: 337px;"/></span></p>
<enun id="example1o3o2o5o3" type="LONG">

<h4 class="enunlong"><i>Examples</i></h4>
<st enunid="enunsec1o3o2o5" secnum="enun1.3.2.5">Examples</st>
<p/>
<div id="l1o3o2o5o1" class="lUNORD">
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<td>
<ul class="none"><li><a name="li1o3o2o5o1o1"/><p>(i) The lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> spanned by the vectors<span class="fd"><a name="fdu19"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd11.svg" alt="[{\bf a} = \pmatrix{ 1 \cr 1 \cr 1 },\quad {\bf b} = \pmatrix{ 1 \cr 1 \cr 0 },\quad {\bf c} = \pmatrix{ 1 \cr -1 \cr 0 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 232px;"/></span>has metric tensor<span class="fd"><a name="fdu20"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd12.svg" alt="[{\bi G} = \pmatrix{ 3 &amp; 2 &amp; 0 \cr 2 &amp; 2 &amp; 0 \cr 0 &amp; 0 &amp; 2 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 113px;"/></span>The inverse of the metric tensor is <span class="fd"><a name="fdu1o3o2o20"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd36.svg" alt="[ {\bi G}^* = {\bi G}^{-1} = {{1}\over{2}} \pmatrix{ 2 &amp; -2 &amp; 0 \cr -2 &amp; 3 &amp; 0 \cr 0 &amp; 0 &amp; 1 }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 195px;"/></span>Interpreting the columns of <img src="/teximages/acch1o3/acch1o3fi334.svg" alt="[{\bi G}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214390000000002pt;"/> as coordinate vectors with respect to the original basis, one concludes that the reciprocal basis is given by <span class="fd"><a name="fdu1o3o2o21"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd37.svg" alt="[ {\bf a}^* = {\bf a} - {\bf b}, \quad {\bf b}^* = \textstyle{{1}\over{2}} (-2 {\bf a} + 3 {\bf b}), \quad {\bf c}^* = \textstyle{{1}\over{2}} {\bf c}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 261px;"/></span>Inserting the columns for <span class="b"><b>a</b></span>, <span class="b"><b>b</b></span>, <span class="b"><b>c</b></span>, one obtains <span class="fd"><a name="fdu1o3o2o22"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd38.svg" alt="[ {\bf a}^* = \pmatrix{ 0 \cr 0 \cr 1 }, \quad {\bf b}^* = {{1}\over{2}} \pmatrix{ 1 \cr 1 \cr -2 }, \quad {\bf c}^* = {{1}\over{2}} \pmatrix{ 1 \cr -1 \cr 0 }. ]" class="mathimage" style="max-width: 100%; height: auto; width: 296px;"/></span></p>
<p>For the direct computation, the matrix <img src="/teximages/acch1o1/acch1o1fi146.svg" alt="[{\bi B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with the basis vectors <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> as columns is<span class="fd"><a name="fdu21"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd39.svg" alt="[{\bi B} = \pmatrix{ 1 &amp; 1 &amp; 1 \cr 1 &amp; 1 &amp; -1 \cr 1 &amp; 0 &amp; 0 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 115px;"/></span>and has as its inverse the matrix<span class="fd"><a name="fdu22"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd40.svg" alt="[{\bi B}^{-1} = {{1}\over{2}} \pmatrix{ 0 &amp; 0 &amp; 2 \cr 1 &amp; 1 &amp; -2 \cr 1 &amp; -1 &amp; 0 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 162px;"/></span>The rows of this matrix are indeed the vectors <img src="/teximages/acch1o3/acch1o3fi283.svg" alt="[{\bf a}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o3/acch1o3fi288.svg" alt="[{\bf b}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <img src="/teximages/acch1o3/acch1o3fi289.svg" alt="[{\bf c}^*]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/> as computed above.</p>
</li>
<li><a name="li1o3o2o5o1o2"/><p>(ii) The body-centred cubic lattice <img src="/teximages/acch1o3/acch1o3fi122.svg" alt="[{\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> has the vectors<span class="fd"><a name="fdu23"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd41.svg" alt="[{\bf a} = {{1}\over{2}} \pmatrix{ -1 \cr 1 \cr 1 }, \quad {\bf b} = {{1}\over{2}} \pmatrix{ 1 \cr -1 \cr 1 },\quad {\bf c} = {{1}\over{2}} \pmatrix{ 1 \cr 1 \cr -1 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 294px;"/></span>as primitive basis.</p>
<p>The matrix<span class="fd"><a name="fdu24"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd42.svg" alt="[{\bi B} = {{1}\over{2}} \pmatrix{-1 &amp; 1 &amp; 1 \cr 1 &amp;-1 &amp; 1 \cr 1 &amp; 1 &amp;-1 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 152px;"/></span>with the basis vectors <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> as columns has as its inverse the matrix<span class="fd"><a name="fdu25"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd43.svg" alt="[{\bi B}^{-1} = \pmatrix{ 0 &amp; 1 &amp; 1 \cr 1 &amp; 0 &amp; 1 \cr 1 &amp; 1 &amp; 0 } .]" class="mathimage" style="max-width: 100%; height: auto; width: 126px;"/></span>The rows of <img src="/teximages/acch1o3/acch1o3fi349.svg" alt="[{\bi B}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.00000000102796e-06pt;"/> are the vectors <span class="fd"><a name="fdu1o3o2o23"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd44.svg" alt="[ {\bf a}^* = \pmatrix{ 0 \cr 1 \cr 1 }, \quad {\bf b}^* = \pmatrix{ 1 \cr 0 \cr 1 }, \quad {\bf c}^* = \pmatrix{ 1 \cr 1 \cr 0 }, ]" class="mathimage" style="max-width: 100%; height: auto; width: 247px;"/></span>showing that the reciprocal lattice of a body-centred cubic lattice is a face-centred cubic lattice.</p>
</li>
</ul></td>
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</tbody>
</table>
</div>
<p>
</p>
</enun>
<p>
</p>
</div>
</div>

<div id="divsec1o3o3" class="sec1" secnum="1.3.3" fpage="28" lpage="31">
<div class="sectionheaders">
<h3 class="sectionheaders"><a name="sec1o3o3"><tree level="1"/></a>1.3.3. The structure of space groups</h3>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o3.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o3" secnum="1.3.3">The structure of space groups</st>

<div id="divsec1o3o3o1" class="sec2" secnum="1.3.3.1" fpage="28" lpage="29">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o3o1"><tree level="2"/></a>1.3.3.1. Point groups of space groups</h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o3o1.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o3o1" secnum="1.3.3.1">Point groups of space groups</st>
<p>The multiplication rule for symmetry operations <span class="fd"><a name="fdu1o3o3o1"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd45.svg" alt="[ ({\bi W}_2, \, {\bi w}_2) ({\bi W}_1, \, {\bi w}_1) = ({\bi W}_2 {\bi W}_1, \, {\bi W}_2 {\bi w}_1 + {\bi w}_2) ]" class="mathimage" style="max-width: 100%; height: auto; width: 246px;"/></span>shows that the mapping <img src="/teximages/acch1o3/acch1o3fi366.svg" alt="[\Pi: ({\bi W}, {\bi w})\, \mapsto\, {\bi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> which assigns a space-group operation to its linear part is actually a group homomorphism<indexg><index id="acch1o3index00082" significance="standard" type="s">homomorphism</index></indexg>, because the first component of the combined operation is simply the product of the linear parts of the two operations. As a consequence, the linear parts of a space group form a group themselves, which is called the point group of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. The kernel of the homomorphism &#928; consists precisely of the translations <img src="/teximages/acch1o3/acch1o3fi368.svg" alt="[({\bi I}, {\bi t}) \in {\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, and since kernels of homomorphisms<indexg><index type="s" significance="standard" id="acch1o3index00083">kernel of a homomorphism</index><index type="s" significance="standard" id="acch1o3index00084">homomorphism<index significance="standard" id="acch1o3index00085" type="s">kernel of</index></index></indexg> are always normal subgroups (<span class="it"><i>cf.</i></span> Section <related volume="A" revision="c" chnum="1.6" url="/Ac/ch1o6v0001/#sec1o1o6"><relchtitle>Methods of space-group determination</relchtitle><relau>U. Shmueli</relau><relau>H. D. Flack</relau><relau>J. C. H. Spence</relau></related>1.1.6<a href="/Ac/ch1o6v0001/#sec1o1o6"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
), the translation subgroup <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> forms a normal subgroup of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. According to the <span class="it"><i>homomorphism theorem</i></span> (see Section <related volume="A" revision="c" chnum="1.6" url="/Ac/ch1o6v0001/#sec1o1o6"><relchtitle>Methods of space-group determination</relchtitle><relau>U. Shmueli</relau><relau>H. D. Flack</relau><relau>J. C. H. Spence</relau></related>1.1.6<a href="/Ac/ch1o6v0001/#sec1o1o6"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
), the point group is isomorphic to the factor group <img src="/teximages/acch1o3/acch1o3fi371.svg" alt="[{\cal G} / {\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>.</p>
<enun id="definition1o3o3o1o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o3o1" secnum="enun1.3.3.1">Definition</st>
<p>The <span class="it"><i>point group</i></span><indexg><index type="s" significance="standard" id="acch1o3index00086">point groups</index></indexg> <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of a space group <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is the group of linear parts of operations occurring in <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. It is isomorphic to the factor group <img src="/teximages/acch1o3/acch1o3fi375.svg" alt="[{\cal G} / {\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by the translation subgroup <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>.</p>
<p>When <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is considered with respect to a coordinate system, the operations of <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> are simply 3 &#215; 3 matrices.</p>
</enun>
<p>
</p>
<p>The point group plays an important role in the analysis of the macroscopic properties of crystals: it describes the symmetry of the set of face normals and can thus be directly observed. It is usually obtained from the <span class="it"><i>diffraction record</i></span> of the crystal, where adding the information about the translation subgroup explains the sharpness of the Bragg peaks in the diffraction pattern.</p>
<p>Although we have already deduced that the translation subgroup <img src="/teximages/acch1o3/acch1o3fi380.svg" alt="[{\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> of a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> forms a normal subgroup in <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> because it is the kernel of the homomorphism mapping each operation to its linear part, it is worth investigating this fact by an explicit computation. Let <img src="/teximages/acch1o3/acch1o3fi383.svg" alt="[\ispecialfonts{\sfi t} = ({\bi I}, \, {\bi t})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> be a translation in <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> and <img src="/teximages/acch1o3/acch1o3fi385.svg" alt="[\ispecialfonts{\sfi W} = ({\bi W}, \, {\bi w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> an arbitrary operation in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, then one has <span class="fd"><a name="fdu1o3o3o2"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd46.svg" alt="[\ispecialfonts \eqalign{ {\sfi W} {\sfi t} {\sfi W}^{-1} &amp;= ({\bi W}, \, {\bi w}) ({\bi I}, \, {\bi t}) ({\bi W}^{-1}, \, -{\bi W}^{-1} {\bi w}) \cr &amp;= ({\bi W}, \, {\bi W} {\bi t} + {\bi w}) ({\bi W}^{-1}, \, -{\bi W}^{-1} {\bi w}) \cr &amp;= ({\bi I}, \, -{\bi w} + {\bi W} {\bi t} + {\bi w}) = ({\bi I}, \, {\bi W} {\bi t}), }]" class="mathimage" style="max-width: 100%; height: auto; width: 230px;"/></span>which is again a translation in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, namely by <img src="/teximages/acch1o3/acch1o3fi388.svg" alt="[{\bi W} {\bi t} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/>. This little computation shows an important property of the translation subgroup with respect to the point group, namely that every vector from the translation lattice is mapped again to a lattice vector by each operation of the point group of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>.</p>
<enun id="proposition1o3o3o1o2" type="SHORT">
<st enunid="enunsec1o3o3o1" secnum="enun1.3.3.1">Proposition.</st>
<p><span class="enunshort"><i>Proposition.</i></span>&#160;Let <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> be a space group with point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and translation subgroup <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> and let <img src="/teximages/acch1o3/acch1o3fi393.svg" alt="[{\bf L} = \{ {\bi t} \mid ({\bi I}, {\bi t}) \in {\cal T} \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> be the lattice of translations in <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>. Then <img src="/teximages/acch1o3/acch1o3fi395.svg" alt="[{\cal P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> acts on the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, <span class="it"><i>i.e.</i></span> for every <img src="/teximages/acch1o3/acch1o3fi397.svg" alt="[{\bi W} \in {\cal P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi398.svg" alt="[{\bi t} \in {\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478206999999996pt;"/> one has <img src="/teximages/acch1o3/acch1o3fi399.svg" alt="[{\bi W} {\bi t} \in {\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478206999999996pt;"/>.</p>
</enun>
<p>
</p>
<p>A point group that acts on a lattice is a subgroup of the full group of symmetries of the lattice, obtained as the group of orthogonal mappings that map the lattice to itself. With respect to a primitive basis, the group of symmetries of a lattice consists of all integral basis transformations that fix the metric tensor of the lattice.</p>
<enun id="definition1o3o3o1o3" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o3o1" secnum="enun1.3.3.1">Definition</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> be a three-dimensional lattice with metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> with respect to a primitive basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
<div id="l1o3o3o1o1" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o3o1o1o1"/><p>(i) An <span class="it"><i>automorphism</i></span> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is an isometry mapping <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> to itself. Written with respect to the basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, an automorphism of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is an integral basis transformation fixing the metric tensor of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, <span class="it"><i>i.e.</i></span> it is an integral matrix <img src="/teximages/acch1o3/acch1o3fi408.svg" alt="[{\bi W} \in {\rm GL}_3({\bb Z})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;"/> with <img src="/teximages/acch1o3/acch1o3fi409.svg" alt="[{\bi W}^{\rm T} \cdot {\bi G} \cdot {\bi W} = {\bi G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999997pt;"/>.</p>
</li>
<li><a name="li1o3o3o1o1o2"/><p>(ii) The group <span class="fd"><a name="fdu1o3o3o3"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd47.svg" alt="[ {\cal B}: = Aut({\bf L}) = \{ {\bi W} \in {\rm GL}_3({\bb Z}) \mid {\bi W}^{\rm T} \cdot {\bi G} \cdot {\bi W} = {\bi G} \} ]" class="mathimage" style="max-width: 100%; height: auto; width: 288px;"/></span>of all automorphisms of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is called the <span class="it"><i>automorphism group</i></span><indexg><index id="acch1o3index00087" significance="standard" type="s">automorphism group</index></indexg> or <span class="it"><i>Bravais group</i></span><indexg><index type="s" significance="standard" id="acch1o3index00088">Bravais group</index></indexg> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Note that <img src="/teximages/acch1o3/acch1o3fi412.svg" alt="[Aut({\bf L}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> acts on the coordinate columns of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, which are simply columns with integral coordinates.</p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
</p>
</enun>
<p>
</p>
<p>Since the isometries in the Bravais group of a lattice preserve distances, the possible images of the vectors in a basis are vectors of the same lengths as the basis vectors. But due to its discreteness, a lattice contains only finitely many lattice vectors up to a given length. This means that a lattice automorphism can only permute the finitely many vectors up to the maximum length of a basis vector. Thus, there can only be finitely many automorphisms of a lattice. This argument proves the following important fact:</p>
<enun id="theorem1o3o3o1o4" type="SHORT">
<st enunid="enunsec1o3o3o1" secnum="enun1.3.3.1">Theorem.</st>
<p><span class="enunshort"><i>Theorem.</i></span>&#160;The Bravais group of a lattice is finite. As a consequence, point groups of space groups are finite groups.</p>
</enun>
<p>
</p>
<p>As subgroups of the Bravais group of a lattice, point groups can be realized as integral matrix groups when written with respect to a primitive basis. For a centred lattice, it is possible that the Bravais group of a lattice contains non-integral matrices, because the centring vector is a column with non-integral entries. However, in dimensions two and three the conventional bases are chosen such that the Bravais groups of all lattices are integral when written with respect to a conventional basis.</p>
<p>Information on the Bravais groups of the primitive lattices in two- and three-dimensional space is displayed in Tables 1.3.3.1<tabler id="table1o3o3o1" loc="float"/> and 1.3.3.2<tabler id="table1o3o3o2" loc="float"/>. The columns of the tables contain the names of the lattices, the metric tensor with respect to the conventional basis (with only the upper half given, the lower half following by the symmetry of the metric tensor), the Hermann&#8211;Mauguin symbol for the type of the Bravais group and generators of the Bravais group (given in the shorthand notation introduced in Section <related volume="A" revision="c" chnum="2.1" url="/Ac/ch2o1v0001/#sec1o2o2o1"><relchtitle>Guide to the use of the space-group tables</relchtitle><relau>Th. Hahn</relau><relau>A. Looijenga-Vos</relau><relau>M. I. Aroyo</relau><relau>H. D. Flack</relau><relau>K. Momma</relau><relau>P. Konstantinov</relau></related>1.2.2.1<a href="/Ac/ch2o1v0001/#sec1o2o2o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 and the corresponding Seitz symbols discussed in Section <related volume="A" revision="c" chnum="1.4" url="/Ac/ch1o4v0001/#sec1o4o2o2"><relchtitle>Space groups and their descriptions</relchtitle><relau>B. Souvignier</relau><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>G. Chapuis</relau><relau>A. M. Glazer</relau></related>1.4.2.2<a href="/Ac/ch1o4v0001/#sec1o4o2o2"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
).</p>
<tableplace id="table1o3o3o1"/>
<tableplace id="table1o3o3o2"/>
<p>The finiteness and integrality of the point groups has important consequences. For example, it implies the <span class="it"><i>crystallographic restriction</i></span> that rotations in space groups of two- and three-dimensional space can only have orders 1, 2, 3, 4 or 6. On the one hand, an integral matrix clearly has an integral trace.<fnr id="fn1" number="1"/> But a matrix <img src="/teximages/acch1o2/acch1o2fi108.svg" alt="[{\bi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/> with the property that <img src="/teximages/acch1o3/acch1o3fi415.svg" alt="[{\bi W}^k = {\bi I} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999995pt;"/> can be diagonalized over the complex numbers and the diagonal entries have to be <span class="it"><i>k</i></span>th roots of unity, <span class="it"><i>i.e.</i></span> powers of <img src="/teximages/acch1o3/acch1o3fi416.svg" alt="[\zeta_k = \exp({2\pi i/k} )]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>. Since diagonalization does not change the trace, the sum of these <span class="it"><i>k</i></span>th roots of unity still has to be an integer and in particular these roots of unity have to occur in complex conjugate pairs. In dimension 2 this means that the two diagonal entries are complex conjugate and the only possible ways to obtain an integral trace are <img src="/teximages/acch1o3/acch1o3fi417.svg" alt="[\zeta_1 + \zeta_1^{-1} = 2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.839951pt;"/>, <img src="/teximages/acch1o3/acch1o3fi418.svg" alt="[\zeta_2 + \zeta_2^{-1} = -2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.839951pt;"/>, <img src="/teximages/acch1o3/acch1o3fi419.svg" alt="[\zeta_3 + \zeta_3^{-1} = -1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.951116pt;"/>, <img src="/teximages/acch1o3/acch1o3fi420.svg" alt="[\zeta_4 + \zeta_4^{-1} = 0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.839951pt;"/> and <img src="/teximages/acch1o3/acch1o3fi421.svg" alt="[\zeta_6 + \zeta_6^{-1} = 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.951116pt;"/>. In dimension 3 the third diagonal entry does not have a complex conjugate partner, and therefore has to be <img src="/teximages/acch1o3/acch1o3fi136.svg" alt="[\pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Thus the possible orders in dimension 3 are the same as in dimension 2.</p>
<p>A much stronger result was obtained by H. Minkowski (1887<bbr id="bb4"/>). He gave an explicit bound for the maximal power <img src="/teximages/acch1o3/acch1o3fi423.svg" alt="[p^m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> of a prime <span class="it"><i>p</i></span> which can divide the order of an <span class="it"><i>n</i></span>-dimensional finite integral matrix group. In dimension 2 this theorem implies that the orders of the point groups divide 24 and in dimension 3 the orders of the point groups divide 48. The Bravais groups 4<span class="it"><i>mm</i></span> (of order 8) and 6<span class="it"><i>mm</i></span> (of order 12) of the square and hexagonal lattices in dimension 2 and the Bravais group <img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/> (of order 48) of the cubic lattice in dimension 3 show that Minkowski's result is the best possible in these dimensions.</p>
</div>

<div id="divsec1o3o3o2" class="sec2" secnum="1.3.3.2" fpage="29" lpage="31">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o3o2"><tree level="2"/></a>1.3.3.2. Coset decomposition with respect to the translation subgroup<indexg><index type="s" id="acch1o3index00089" significance="standard">coset decomposition</index><index id="acch1o3index00090" significance="standard" type="s">translation subgroup</index><index type="s" id="acch1o3index00091" significance="standard">subgroups<index id="acch1o3index00092" significance="standard" type="s">translation subgroup</index></index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o3o2.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o3o2" secnum="1.3.3.2">Coset decomposition with respect to the translation subgroup<indexg><index type="s" id="acch1o3index00089" significance="standard">coset decomposition</index><index id="acch1o3index00090" significance="standard" type="s">translation subgroup</index><index type="s" id="acch1o3index00091" significance="standard">subgroups<index id="acch1o3index00092" significance="standard" type="s">translation subgroup</index></index></indexg></st>
<p>The translation subgroup <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> of a space group <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> can be used to distribute the operations of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> into different classes by grouping together all operations that differ only by a translation. This results in the decomposition of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> into cosets with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> (see <related volume="A" revision="c" chnum="1.1" url="/Ac/ch1o1v0001/#sec1o1o4"><relchtitle>A general introduction to groups</relchtitle><relau>B. Souvignier</relau></related>Section 1.1.4<a href="/Ac/ch1o1v0001/#sec1o1o4"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 for details of cosets).</p>
<enun id="definition1o3o3o2o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o3o2" secnum="enun1.3.3.2">Definition</st>
<p>Let <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> be a space group with translation subgroup <img src="/teximages/acch1o3/acch1o3fi380.svg" alt="[{\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>.</p>
<div id="l1o3o3o2o1" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o3o2o1o1"/><p>(i) The <span class="it"><i>right coset</i></span> <img src="/teximages/acch1o3/acch1o3fi432.svg" alt="[\ispecialfonts{\cal T} {\sfi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> of an operation <img src="/teximages/acch1o3/acch1o3fi433.svg" alt="[\ispecialfonts{\sfi W} \in {\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> is the set <img src="/teximages/acch1o3/acch1o3fi435.svg" alt="[\ispecialfonts\{ {\sfi t} {\sfi W} \mid {\sfi t} \in {\cal T} \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>.</p>
<p>Analogously, the set <img src="/teximages/acch1o3/acch1o3fi436.svg" alt="[\ispecialfonts{\sfi W} {\cal T} = \{ {\sfi W} {\sfi t} \mid {\sfi t} \in {\cal T} \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> is called the <span class="it"><i>left coset</i></span> of <img src="/teximages/acch1o3/acch1o3fi437.svg" alt="[\ispecialfonts{\sfi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>.</p>
</li>
<li><a name="li1o3o3o2o1o2"/><p>(ii) A set <img src="/teximages/acch1o3/acch1o3fi439.svg" alt="[\ispecialfonts\{ {\sfi W}_1, \ldots, {\sfi W}_m \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> of operations in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is called a system of <span class="it"><i>coset representatives</i></span><indexg><index id="acch1o3index00093" significance="standard" type="s">coset representatives</index></indexg> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> if every operation <img src="/teximages/acch1o3/acch1o3fi437.svg" alt="[\ispecialfonts{\sfi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is contained in exactly one coset <img src="/teximages/acch1o3/acch1o3fi444.svg" alt="[\ispecialfonts{\cal T} {\sfi W}_i ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/>.</p>
</li>
<li><a name="li1o3o3o2o1o3"/><p>(iii) Writing <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> as the disjoint union <span class="fd"><a name="fdu1o3o3o4"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd48.svg" alt="[ \ispecialfonts{\cal G} = {\cal T} {\sfi W}_1 \cup \ldots \cup {\cal T} {\sfi W}_m ]" class="mathimage" style="max-width: 100%; height: auto; width: 137px;"/></span>is called the <span class="it"><i>coset decomposition of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/></i></span>.</p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
</p>
</enun>
<p>
</p>
<p>If the translation subgroup <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> is a subgroup of index [<span class="it"><i>i</i></span>] in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, a set of coset representatives for <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> consists of [<span class="it"><i>i</i></span>] operations <img src="/teximages/acch1o3/acch1o3fi452.svg" alt="[\ispecialfonts{\sfi W}_1, {\sfi W}_2, \ldots, {\sfi W}_{[i]}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.031956pt;"/>, where <img src="/teximages/acch1o3/acch1o3fi453.svg" alt="[\ispecialfonts{\sfi W}_1 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> is assumed to be the identity element <img src="/teximages/acpre6/acpre6fi54.svg" alt="[\ispecialfonts{\sfi e}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.228284999999996pt;"/> of <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. The cosets of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> can be imagined as columns of an infinite array with [<span class="it"><i>i</i></span>] columns, labelled by the coset representatives, as displayed in Table 1.3.3.3<tabler id="table1o3o3o3" loc="float"/>.</p>
<tableplace id="table1o3o3o3"/>
<p><span class="it"><i>Remark</i></span>: We can assume some enumeration <img src="/teximages/acch1o3/acch1o3fi458.svg" alt="[\ispecialfonts{\sfi t}_1, {\sfi t}_2, {\sfi t}_3, \ldots ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of the operations in <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> because the translation vectors form a lattice. For example, with respect to a primitive basis, the coordinate vectors of the translations in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> are simply columns <img src="/teximages/acch1o3/acch1o3fi461.svg" alt="[\pmatrix{ l \cr m \cr n }]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -14.933975pt;"/> with integral components <img src="/teximages/acch1o3/acch1o3fi462.svg" alt="[l,m,n]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307347pt;"/>. A straightforward enumeration of these columns would start with <span class="fd"><a name="fdu1o3o3o5"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd49.svg" alt="[\eqalign{&amp;\pmatrix{ 0 \cr 0 \cr 0 }, \, \pmatrix{ 1 \cr 0 \cr 0 }, \, \pmatrix{ 0 \cr 1 \cr 0 }, \, \pmatrix{ 0 \cr 0 \cr 1 }, \, \pmatrix{ \bar{1} \cr 0 \cr 0 }, \, \pmatrix{ 0 \cr \bar{1} \cr 0 }, \, \pmatrix{ 0 \cr 0 \cr \bar{1} }, \cr &amp; \pmatrix{ 1 \cr 1 \cr 0 }, \, \pmatrix{ 1 \cr 0 \cr 1 }, \, \pmatrix{ 0 \cr 1 \cr 1 } \ldots }]" class="mathimage" style="max-width: 100%; height: auto; width: 311px;"/></span></p>
<p>Writing out the matrix&#8211;column pairs, the coset <img src="/teximages/acch1o3/acch1o3fi463.svg" alt="[{\cal T} ({\bi W}, {\bi w}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> consists of the operations of the form <img src="/teximages/acch1o3/acch1o3fi464.svg" alt="[({\bi I}, {\bi t}) ({\bi W}, {\bi w}) = ({\bi W}, {\bi w} + {\bi t}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with <img src="/teximages/acch1o3/acch1o3fi465.svg" alt="[{\bi t}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999995pt;"/> running over the lattice translations of <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>. This means that the operations of a coset with respect to the translation subgroup all have the same linear part, which is also evident from a listing of the cosets as columns of an infinite array, as in the example above.</p>
<enun id="proposition1o3o3o2o2" type="LONG">

<h4 class="enunlong"><i>Proposition</i></h4>
<st enunid="enunsec1o3o3o2" secnum="enun1.3.3.2">Proposition</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi467.svg" alt="[\ispecialfonts{\sfi W} = ({\bi W}, {\bi w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> and <img src="/teximages/acch1o3/acch1o3fi468.svg" alt="[\ispecialfonts{\sfi W}' = ({\bi W}', {\bi w}') ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> be two operations of a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> with translation subgroup <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>.</p>
<div id="l1o3o3o2o2" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o3o2o2o1"/><p>(1) If <img src="/teximages/acch1o3/acch1o3fi471.svg" alt="[{\bi W} \neq {\bi W}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.582317pt;"/>, then the cosets <img src="/teximages/acch1o3/acch1o3fi472.svg" alt="[\ispecialfonts{\cal T} {\sfi W} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> and <img src="/teximages/acch1o3/acch1o3fi473.svg" alt="[\ispecialfonts{\cal T} {\sfi W}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> are disjoint, <span class="it"><i>i.e.</i></span> their intersection is empty.</p>
</li>
<li><a name="li1o3o3o2o2o2"/><p>(2) If <img src="/teximages/acch1o3/acch1o3fi474.svg" alt="[{\bi W} = {\bi W}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389000000001pt;"/>, then the cosets <img src="/teximages/acch1o3/acch1o3fi432.svg" alt="[\ispecialfonts{\cal T} {\sfi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> and <img src="/teximages/acch1o3/acch1o3fi473.svg" alt="[\ispecialfonts{\cal T} {\sfi W}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> are equal, because <img src="/teximages/acch1o3/acch1o3fi477.svg" alt="[\ispecialfonts{\sfi W} {\sfi W}'^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.00000000102796e-06pt;"/> has linear part <img src="/teximages/acch1o3/acch1o3fi16.svg" alt="[{\bi I}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and is thus an operation contained in <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>.</p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
</p>
</enun>
<p>
</p>
<p>The one-to-one correspondence between the point-group operations and the cosets relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> explicitly displays the isomorphism between the point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and the factor group <img src="/teximages/acch1o3/acch1o3fi483.svg" alt="[{\cal G}/{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>. This correspondence is also exploited in the listing of the general-position coordinates. What is given there are the coordinate triplets for coset representatives of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> relative to <img src="/teximages/acch1o3/acch1o3fi380.svg" alt="[{\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>, which correspond to the first row of the array in Table 1.3.3.3<tabler id="table1o3o3o3" loc="float"/>. As just explained, the other operations in <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> can be obtained from these coset representatives by adding a lattice translation to the translational part.</p>
<p>Furthermore, the correspondence between the point group and the coset decomposition relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> makes it easy to find a system of coset representatives <img src="/teximages/acch1o3/acch1o3fi488.svg" alt="[\ispecialfonts\{ {\sfi W}_1, \ldots, {\sfi W}_m \}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>. What is required is that the linear parts of the <img src="/teximages/acch1o3/acch1o3fi491.svg" alt="[\ispecialfonts{\sfi W}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> are precisely the operations in the point group of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. If <img src="/teximages/acch1o3/acch1o3fi493.svg" alt="[{\bi W}_1, \ldots, {\bi W}_m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> are the different operations in the point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, then a system of coset representatives is obtained by choosing for every linear part <img src="/teximages/acch1o3/acch1o3fi496.svg" alt="[{\bi W}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> a translation part <img src="/teximages/acch1o3/acch1o3fi497.svg" alt="[{\bi w}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> such that <img src="/teximages/acch1o3/acch1o3fi498.svg" alt="[\ispecialfonts{\sfi W}_i = ({\bi W}_i, {\bi w}_i)]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is an operation in <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>.</p>
<p>It is customary to choose the translation parts <img src="/teximages/acch1o3/acch1o3fi497.svg" alt="[{\bi w}_i]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.880607pt;"/> of the coset representatives such that their coordinates lie between 0 and 1, excluding 1. In particular, if the translation part of a coset representative is a lattice vector, it is usually chosen as the zero vector <img src="/teximages/acch1o3/acch1o3fi501.svg" alt="[{\bi o}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/>.</p>
<p>Note that due to the fact that <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> is a normal subgroup of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, a system of coset representatives for the right cosets is at the same time a system of coset representatives for the left cosets.</p>
</div>

<div id="divsec1o3o3o3" class="sec2" secnum="1.3.3.3" fpage="31" lpage="31">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o3o3"><tree level="2"/></a>1.3.3.3. Symmorphic and non-symmorphic space groups<indexg><index id="acch1o3index00094" significance="standard" type="s">space groups<index id="acch1o3index00095" significance="standard" type="s">symmorphic</index></index><index type="s" significance="standard" id="acch1o3index00096">space groups<index id="acch1o3index00097" significance="standard" type="s">non-symmorphic</index></index><index id="acch1o3index00098" significance="standard" type="s">non-symmorphic space groups</index><index type="s" significance="standard" id="acch1o3index00099">symmorphic space groups</index></indexg></h4>
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</div>
<st secid="sec1o3o3o3" secnum="1.3.3.3">Symmorphic and non-symmorphic space groups<indexg><index id="acch1o3index00094" significance="standard" type="s">space groups<index id="acch1o3index00095" significance="standard" type="s">symmorphic</index></index><index type="s" significance="standard" id="acch1o3index00096">space groups<index id="acch1o3index00097" significance="standard" type="s">non-symmorphic</index></index><index id="acch1o3index00098" significance="standard" type="s">non-symmorphic space groups</index><index type="s" significance="standard" id="acch1o3index00099">symmorphic space groups</index></indexg></st>
<p>If a coset with respect to the translation subgroup contains an operation of the form <img src="/teximages/abch11o2/abch11o2fi11.svg" alt="[({\bi W}, {\bi w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with <img src="/teximages/abch12o2/abch12o2fi15.svg" alt="[{\bi w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/> a vector in the translation lattice, it is clear that the same coset also contains the operation <img src="/teximages/acch1o3/acch1o3fi506.svg" alt="[({\bi W}, {\bi o})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with trivial translation part. On the other hand, if a coset does not contain an operation of the form <img src="/teximages/acch1o3/acch1o3fi507.svg" alt="[({\bi W}, {\bi o}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>, this may be caused by an inappropriate choice of origin<indexg><index id="acch1o3index00100" significance="standard" type="s">origin choice</index></indexg>. For example, the operation <img src="/teximages/acch1o3/acch1o3fi508.svg" alt="[(-{\bi I}, (1/2,1/2,1/2))]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> is turned into the inversion <img src="/teximages/acch1o3/acch1o3fi509.svg" alt="[(-{\bi I}, (0,0,0))]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> by moving the origin to <img src="/teximages/acch1o3/acch1o3fi510.svg" alt="[1/4,1/4,1/4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (<span class="it"><i>cf.</i></span> Section <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#sec1o5o1o1"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>1.5.1.1<a href="/Ac/ch1o5v0001/#sec1o5o1o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 for a detailed treatment of origin-shift transformations).</p>
<p>Depending on the actual space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, it may or may not be possible to choose the origin such that every coset with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> contains an operation of the form <img src="/teximages/acch1o3/acch1o3fi506.svg" alt="[({\bi W}, {\bi o})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
<enun id="definition1o3o3o3o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o3o3" secnum="enun1.3.3.3">Definition</st>
<p>Let <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> be a space group with translation subgroup <img src="/teximages/acch1o3/acch1o3fi380.svg" alt="[{\cal T} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/>. If it is possible to choose the coordinate system such that every coset of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> contains an operation <img src="/teximages/acch1o3/acch1o3fi506.svg" alt="[({\bi W}, {\bi o})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with trivial translation part, <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is called a <span class="it"><i>symmorphic</i></span> space group, otherwise <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is called a <span class="it"><i>non-symmorphic</i></span> space group.</p>
</enun>
<p>
</p>
<p>One sees that the operations with trivial translation part form a subgroup of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> which is isomorphic to a subgroup of the point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>. This subgroup is the group of operations in <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> that fix the origin and is called the <span class="it"><i>site-symmetry group</i></span><indexg><index id="acch1o3index00101" significance="standard" type="s">site-symmetry group</index></indexg> of the origin (site-symmetry groups are discussed in detail in Section <related volume="A" revision="c" chnum="1.4" url="/Ac/ch1o4v0001/#sec1o4o4"><relchtitle>Space groups and their descriptions</relchtitle><relau>B. Souvignier</relau><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>G. Chapuis</relau><relau>A. M. Glazer</relau></related>1.4.4<a href="/Ac/ch1o4v0001/#sec1o4o4"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
). It is the distinctive property of symmorphic space groups that they contain a subgroup which is isomorphic to the full point group. This may in fact be seen as an alternative definition for symmorphic space groups.</p>
<enun id="proposition1o3o3o3o2" type="SHORT">
<st enunid="enunsec1o3o3o3" secnum="enun1.3.3.3">Proposition.</st>
<p><span class="enunshort"><i>Proposition.</i></span>&#160;A space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> with point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> is symmorphic if and only if it contains a subgroup isomorphic to <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>. For a non-symmorphic space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>, every finite subgroup of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is isomorphic to a proper subgroup of the point group.</p>
</enun>
<p>
</p>
<p>Note that every finite subgroup of a space group is a subgroup of the site-symmetry group for some point, because finite groups cannot contain translations. Therefore, a symmorphic space group is characterized by the fact that it contains a site-symmetry group isomorphic to its point group, whereas in non-symmorphic space groups all site-symmetry groups have orders strictly smaller than the order of the point group.</p>
<p>Symmorphic space groups can easily be constructed by choosing a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and a point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> which acts on <img src="/teximages/acch1o3/acch1o3fi122.svg" alt="[{\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Then <img src="/teximages/acch1o3/acch1o3fi532.svg" alt="[{\cal G} = \{ ({\bi W}, {\bi w}) \mid {\bi W} \in {\cal P}, {\bi w} \in {\bf L} \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> is a space group in which the coset representatives can be chosen as <img src="/teximages/acch1o3/acch1o3fi533.svg" alt="[({\bi W}, \, {\bi o})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
<p>Non-symmorphic space groups can also be constructed from a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and a point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>. What is required is a system of coset representatives with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> and these are obtained by choosing for each operation <img src="/teximages/acch1o3/acch1o3fi537.svg" alt="[{\bi W} \in {\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> a translation part <img src="/teximages/abch12o2/abch12o2fi15.svg" alt="[{\bi w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/>. Owing to the translations, it is sufficient to consider vectors <img src="/teximages/abch12o2/abch12o2fi15.svg" alt="[{\bi w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/> with components between 0 and 1. However, the translation parts cannot be chosen arbitrarily, because for a point-group operation of order <span class="it"><i>k</i></span>, the operation <img src="/teximages/acch1o3/acch1o3fi540.svg" alt="[({\bi W}, {\bi w})^k ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.30734699999999pt;"/> has to be a translation <img src="/teximages/acch1o3/acch1o3fi541.svg" alt="[({\bi I}, {\bi t})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with <img src="/teximages/acch1o3/acch1o3fi542.svg" alt="[{\bi t} \in {\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478206999999996pt;"/>. Working this out, this imposes the restriction that <span class="fd"><a name="fdu1o3o3o6"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd50.svg" alt="[ ({\bi W}^{k-1} + \ldots + {\bi W} + {\bi I}) {\bi w} \in {\bf L}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 167px;"/></span>Once translation parts <img src="/teximages/abch12o2/abch12o2fi15.svg" alt="[{\bi w}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/> are found that fulfil all these restrictions, one finally has to check whether the space group obtained this way is (by accident) symmorphic, but written with respect to an inappropriate origin. A change of origin by <img src="/teximages/acch1o3/acch1o3fi544.svg" alt="[{\bi p}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> is realized by conjugating the matrix&#8211;column pair <img src="/teximages/abch11o2/abch11o2fi11.svg" alt="[({\bi W}, {\bi w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> by the translation <img src="/teximages/acch1o3/acch1o3fi546.svg" alt="[({\bi I}, -{\bi p})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> (<span class="it"><i>cf.</i></span> Section <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/#sec1o5o1"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>1.5.1<a href="/Ac/ch1o5v0001/#sec1o5o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 on transformations of the coordinate system) which gives<span class="fd"><a name="fdu1o3o3o7"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd51.svg" alt="[ ({\bi I}, -{\bi p}) ({\bi W}, {\bi w}) ({\bi I}, {\bi p}) = ({\bi W}, {\bi W} {\bi p} + {\bi w} - {\bi p}) = ({\bi W}, {\bi w} + ({\bi W} - {\bi I}) {\bi p}). ]" class="mathimage" style="max-width: 100%; height: auto; width: 363px;"/></span>Thus, the space group just constructed is symmorphic if there is a vector <img src="/teximages/acch1o3/acch1o3fi544.svg" alt="[{\bi p}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> such that <img src="/teximages/acch1o3/acch1o3fi548.svg" alt="[({\bi W} - {\bi I}) {\bi p} + {\bi w} \in {\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> for each of the coset representatives <img src="/teximages/abch11o2/abch11o2fi11.svg" alt="[({\bi W}, {\bi w})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>.</p>
<p>The above considerations also show how every space group can be assigned to a symmorphic space group in a canonical way, namely by setting the translation parts of coset representatives with respect to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;"/> to <img src="/teximages/acch1o3/acch1o3fi551.svg" alt="[{\bi o} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/>. This has the effect that screw rotations are turned into rotations and glide reflections into reflections. The Hermann&#8211;Mauguin symbol (see Section <related volume="A" revision="c" chnum="1.4" url="/Ac/ch1o4v0001/#sec1o4o1"><relchtitle>Space groups and their descriptions</relchtitle><relau>B. Souvignier</relau><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>G. Chapuis</relau><relau>A. M. Glazer</relau></related>1.4.1<a href="/Ac/ch1o4v0001/#sec1o4o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 for a detailed discussion of Hermann&#8211;Mauguin symbols) of the symmorphic space group to which an arbitrary space group is assigned is simply obtained by replacing any screw rotation symbol <span class="it"><i>N</i></span><span class="inf"><sub><span class="it"><i>m</i></span></sub></span> by the corresponding rotation symbol <span class="it"><i>N</i></span> and every glide reflection symbol <span class="it"><i>a</i></span>, <span class="it"><i>b</i></span>, <span class="it"><i>c</i></span>, <span class="it"><i>d</i></span>, <span class="it"><i>e</i></span>, <span class="it"><i>n</i></span> by the symbol <span class="it"><i>m</i></span> for a reflection. A space group is found to be symmorphic if no such replacement is required, <span class="it"><i>i.e.</i></span> if the Hermann&#8211;Mauguin symbol only contains the symbols 1, 2, 3, 4, 6 for rotations, <img src="/teximages/abch1o3/abch1o3fi85.svg" alt="[\bar{1}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 6px;"/>, <img src="/teximages/abch1o4/abch1o4fi128.svg" alt="[\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/>, <img src="/teximages/abch1o4/abch1o4fi129.svg" alt="[\bar{4}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 7px;"/>, <img src="/teximages/abch1o4/abch1o4fi130.svg" alt="[\bar{6}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/> for rotoinversions and <span class="it"><i>m</i></span> for reflections.</p>
<enun id="example1o3o3o3o3" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o3o3" secnum="enun1.3.3.3">Example</st>
<p>The space groups with Hermann-Mauguin symbols <span class="it"><i>P</i></span>4<span class="it"><i>mm</i></span>, <span class="it"><i>P</i></span>4<span class="it"><i>bm</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>cm</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>nm</i></span>, <span class="it"><i>P</i></span>4<span class="it"><i>cc</i></span>, <span class="it"><i>P</i></span>4<span class="it"><i>nc</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>mc</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>bc</i></span> are all assigned to the symmorphic space group with Hermann&#8211;Mauguin symbol <img src="/teximages/acch1o3/acch1o3fi556.svg" alt="[P4mm]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999995pt;"/>.</p>
</enun>
<p>
</p>
</div>
</div>

<div id="divsec1o3o4" class="sec1" secnum="1.3.4" fpage="31" lpage="41">
<div class="sectionheaders">
<h3 class="sectionheaders"><a name="sec1o3o4"><tree level="1"/></a>1.3.4. Classification of space groups<indexg><index type="s" id="acch1o3index00102" significance="standard">space groups<index type="s" significance="standard" id="acch1o3index00103">classification of</index></index></indexg></h3>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4" secnum="1.3.4">Classification of space groups<indexg><index type="s" id="acch1o3index00102" significance="standard">space groups<index type="s" significance="standard" id="acch1o3index00103">classification of</index></index></indexg></st>
<p>In this section we will consider various ways in which space groups may be grouped together. For the space groups themselves, the natural notion of equivalence is the classification into <span class="it"><i>space-group types</i></span>, but the point groups and lattices from which the space groups are built also have their own classification schemes into <span class="it"><i>geometric crystal classes</i></span> and <span class="it"><i>Bravais types of lattices</i></span>, respectively.</p>
<p>Some other types of classifications are relevant for certain applications, and these will also be considered. The hierarchy of the different classification levels and the numbers of classes on the different levels in dimension 3 are displayed in Fig. 1.3.4.1<figr id="fig1o3o4o1" loc="float"/>.</p>
<figplace id="fig1o3o4o1"/>

<div id="divsec1o3o4o1" class="sec2" secnum="1.3.4.1" fpage="31" lpage="33">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o1"><tree level="2"/></a>1.3.4.1. Space-group types<indexg><index type="s" significance="standard" id="acch1o3index00104">space-group types</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o1.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o1" secnum="1.3.4.1">Space-group types<indexg><index type="s" significance="standard" id="acch1o3index00104">space-group types</index></indexg></st>
<p>The main motivation behind studying space groups is that they allow the classification of crystal structures according to their symmetry properties. Since many properties of a structure can be derived from its group of symmetries alone, this allows the investigation of the properties of many structures simultaneously. </p>
<p>On the other hand, even for the same crystal structure the corresponding space group may look different, depending on the chosen coordinate system (see Chapter <related volume="A" revision="c" chnum="1.5" url="/Ac/ch1o5v0001/"><relchtitle>Transformations of coordinate systems</relchtitle><relau>H. Wondratschek</relau><relau>M. I. Aroyo</relau><relau>B. Souvignier</relau><relau>G. Chapuis</relau></related>1.5<a href="/Ac/ch1o5v0001/"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 for a detailed discussion of transformations to different coordinate systems). Because it is natural to regard two realizations of a group of symmetry operations with respect to two different coordinate systems as equivalent, the following notion of equivalence between space groups is natural.</p>
<enun id="definition1o3o4o1o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Definition</st>
<p>Two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> are called <span class="it"><i>affinely equivalent</i></span> if <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> can be obtained from <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by a change of the coordinate system.</p>
<p>In terms of matrix&#8211;column pairs this means that there must exist a matrix&#8211;column pair <img src="/teximages/acch1o3/acch1o3fi561.svg" alt="[({\bi P}, {\bi p})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> such that <span class="fd"><a name="fdu1o3o4o1"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd52.svg" alt="[ {\cal G}' = \{ ({\bi P}, {\bi p})^{-1} ({\bi W}, {\bi w}) ({\bi P}, {\bi p}) \mid ({\bi W}, {\bi w}) \in {\cal G} \}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 250px;"/></span>The collection of space groups that are affinely equivalent with <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> forms the <span class="it"><i>affine type</i></span> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>.</p>
<p>In dimension 2 there are 17 affine types of plane groups and in dimension 3 there are 219 affine space-group types. Note that in order to avoid misunderstandings we refrain from calling the space-group types <span class="it"><i>affine classes</i></span>, since the term classes is usually associated with <span class="it"><i>geometric crystal classes</i></span> (see below).</p>
</enun>
<p>
</p>
<p>Grouping together space groups according to their space-group type serves different purposes. On the one hand, it is sometimes convenient to consider the same crystal structure and thus also its space group with respect to different coordinate systems, <span class="it"><i>e.g.</i></span> when the origin can be chosen in different natural ways or when a phase transition to a higher- or lower-symmetry phase with a different conventional cell is described. On the other hand, different crystal structures may give rise to the same space group once suitable coordinate systems have been chosen for both. We illustrate both of these perspectives by an example.</p>
<enun id="example1o3o4o1o2" type="LONG">

<h4 class="enunlong"><i>Examples</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Examples</st>
<p/>
<div id="l1o3o4o1o1" class="lUNORD">
<table>
<tbody>
<tr>
<td>
<ul class="none"><li><a name="li1o3o4o1o1o1"/><p>(i) The space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> of type <span class="it"><i>Pban</i></span> (50) has a subgroup <img src="/teximages/abch1o1/abch1o1fi100.svg" alt="[{\cal H}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.585803999999998pt;"/> of index 2 for which the coset representatives relative to the translation subgroup are the identity <img src="/teximages/acch1o3/acch1o3fi566.svg" alt="[\ispecialfonts{\sfi e}{:}\ x,y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/>, the twofold rotation <img src="/teximages/acch1o3/acch1o3fi567.svg" alt="[\ispecialfonts{\sfi g}{:}\ {-}x,y,-z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/>, the <span class="it"><i>n</i></span> glide <img src="/teximages/acch1o3/acch1o3fi568.svg" alt="[\ispecialfonts{\sfi h}{:}\ x+\textstyle{{1}\over{2}},y+\textstyle{{1}\over{2}},-z ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.12261700000001pt;"/> and the <span class="it"><i>b</i></span> glide <img src="/teximages/acch1o3/acch1o3fi569.svg" alt="[\ispecialfonts{\sfi k}{:}\ {-}x+{{1}\over{2}},y+{{1}\over{2}},z ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.12261700000001pt;"/>. This subgroup is of type <span class="it"><i>Pb</i></span>2<span class="it"><i>n</i></span>, which is a non-conventional setting for <span class="it"><i>Pnc</i></span>2 (30). In the conventional setting, the coset representatives of <span class="it"><i>Pnc</i></span>2 are given by <img src="/teximages/acch1o3/acch1o3fi570.svg" alt="[\ispecialfonts{\sfi g}'{:}\ {-}x,-y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/>, <img src="/teximages/acch1o3/acch1o3fi571.svg" alt="[\ispecialfonts{\sfi h}'{:}\ {-}x,y+\textstyle{{1}\over{2}},z+\textstyle{{1}\over{2}}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.12261700000001pt;"/> and <img src="/teximages/acch1o3/acch1o3fi572.svg" alt="[\ispecialfonts{\sfi k}'{:}\ x,-y+\textstyle{{1}\over{2}},z+\textstyle{{1}\over{2}} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.12261700000001pt;"/>, <span class="it"><i>i.e.</i></span> with the <span class="it"><i>z</i></span> axis as rotation axis for the twofold rotation. The subgroup <img src="/teximages/abch1o1/abch1o1fi100.svg" alt="[{\cal H}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.585803999999998pt;"/> can be transformed to its conventional setting by the basis transformation <img src="/teximages/acch1o3/acch1o3fi574.svg" alt="[({\bf a}', {\bf b}', {\bf c}') = ({\bf c}, {\bf a}, {\bf b}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/>. Depending on whether the perspective of the full group <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> or the subgroup <img src="/teximages/abch1o1/abch1o1fi100.svg" alt="[{\cal H}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.585803999999998pt;"/> is more important for a crystal structure, the groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch1o1/abch1o1fi100.svg" alt="[{\cal H}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.585803999999998pt;"/> will be considered either with respect to the basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> (conventional for <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>) or to the basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> (conventional for <img src="/teximages/abch1o1/abch1o1fi100.svg" alt="[{\cal H}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.585803999999998pt;"/>).</p>
</li>
<li><a name="li1o3o4o1o1o2"/><p>(ii) The elements carbon, silicon and germanium all crystallize in the <span class="it"><i>diamond structure</i></span>, which has a face-centred cubic unit cell with two atoms shifted by 1/4 along the space diagonal of the conventional cubic cell. The space group is in all cases of type <img src="/teximages/abpre6/abpre6fi16.svg" alt="[Fd\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/> (227), but the cell parameters differ: <span class="it"><i>a</i></span><span class="inf"><sub>C</sub></span> = 3.5668&#8197;&#197; for carbon, <span class="it"><i>a</i></span><span class="inf"><sub>Si</sub></span> = 5.4310&#8197;&#197; for silicon and <span class="it"><i>a</i></span><span class="inf"><sub>Ge</sub></span> = 5.6579&#8197;&#197; for germanium (measured at 298&#8197;K). In order to scale the conventional cell of carbon to that of silicon, the coordinate system has to be transformed by the diagonal matrix<span class="fd"><a name="fdu27"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd53.svg" alt="[a_{\rm Si} / a_{\rm C} \cdot {\bi I}_3 \approx \pmatrix{ 1.523 &amp; 0 &amp; 0 \cr 0 &amp; 1.523 &amp; 0 \cr 0 &amp; 0 &amp; 1.523 } .]" class="mathimage" style="max-width: 100%; height: auto; width: 245px;"/></span></p>
</li>
</ul></td>
</tr>
</tbody>
</table>
</div>
<p>
</p>
</enun>
<p>
</p>
<p>By a famous theorem of Bieberbach (see Bieberbach, 1911<bbr id="bb2"/>, 1912<bbr id="bb3"/>), affine equivalence of space groups actually coincides with the notion of abstract group isomorphism as discussed in Section <related volume="A" revision="c" chnum="1.6" url="/Ac/ch1o6v0001/#sec1o1o6"><relchtitle>Methods of space-group determination</relchtitle><relau>U. Shmueli</relau><relau>H. D. Flack</relau><relau>J. C. H. Spence</relau></related>1.1.6<a href="/Ac/ch1o6v0001/#sec1o1o6"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
.</p>
<enun id="theorem1o3o4o1o3" type="LONG">

<h4 class="enunlong"><i>Bieberbach theorem<indexg><index id="acch1o3index00105" significance="standard" type="s">Bieberbach theorem</index></indexg></i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Bieberbach theorem<indexg><index id="acch1o3index00105" significance="standard" type="s">Bieberbach theorem</index></indexg></st>
<p>Two space groups in <span class="it"><i>n</i></span>-dimensional space are isomorphic if and only if they are conjugate by an affine mapping.</p>
</enun>
<p>
</p>
<p>This theorem is by no means obvious. Recall that for point groups the situation is very different, since for example the abstract cyclic group of order 2 is realized in the point groups of space groups of type <span class="it"><i>P</i></span>2, <span class="it"><i>Pm</i></span> and <img src="/teximages/abch2o2/abch2o2fi15.svg" alt="[P\bar{1}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 16px;"/>, generated by a twofold rotation, reflection and inversion, respectively, which are clearly not equivalent in any geometric sense. The driving force behind the Bieberbach theorem is the special structure of space groups having an infinite normal translation subgroup on which the point group acts.</p>
<p>In crystallography, a notion of equivalence slightly stronger than affine equivalence is usually used. Since crystals occur in physical space and physical space can only be transformed by orientation-preserving mappings, space groups are only regarded as equivalent if they are conjugate by an <span class="it"><i>orientation-preserving</i></span> coordinate transformation, <span class="it"><i>i.e.</i></span> by an affine mapping that has a linear part with positive determinant.</p>
<enun id="definition1o3o4o1o4" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Definition</st>
<p>Two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> are said to belong to the same <span class="it"><i>space-group type</i></span> if <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> can be obtained from <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by an orientation-preserving coordinate transformation, <span class="it"><i>i.e.</i></span> by conjugation with a matrix&#8211;column pair <img src="/teximages/acch1o3/acch1o3fi561.svg" alt="[({\bi P}, {\bi p})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.441654pt;"/> with <img src="/teximages/acch1o3/acch1o3fi590.svg" alt="[\det {\bi P}\,\gt\, 0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478206999999996pt;"/>. In order to distinguish the space-group types explicitly from the affine space-group types (corresponding to the isomorphism classes), they are often called <span class="it"><i>crystallographic space-group types</i></span>.</p>
</enun>
<p>
</p>
<p>The (crystallographic) space-group type collects together the infinitely many space groups that are obtained by expressing a single space group with respect to all possible right-handed coordinate systems for the point space.</p>
<enun id="example1o3o4o1o5" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Example</st>
<p>We consider the space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> of type <img src="/teximages/acch1o3/acch1o3fi592.svg" alt="[I4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (80) which is generated by the right-handed fourfold screw rotation <img src="/teximages/acch1o3/acch1o3fi593.svg" alt="[\ispecialfonts{\sfi g}{:}\ {-}y, x+1/2, z+1/4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (located at <img src="/teximages/acch1o3/acch1o3fi594.svg" alt="[-1/4, 1/4, z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>), the centring translation <img src="/teximages/acch1o3/acch1o3fi595.svg" alt="[\ispecialfonts{\sfi t}{:}\ x+1/2, y+1/2, z+1/2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> and the integral translations of a primitive tetragonal lattice. Conjugating the group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> to <img src="/teximages/acch1o3/acch1o3fi597.svg" alt="[{\cal G}' = \ispecialfonts{\sfi m} {\cal G}{\sfi m}^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by the reflection <img src="/teximages/acch1o3/acch1o3fi598.svg" alt="[\ispecialfonts{\sfi m}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> in the plane <img src="/teximages/acch1o3/acch1o3fi599.svg" alt="[z=0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.964750999999996pt;"/> turns the right-handed screw rotation <img src="/teximages/acch1o1/acch1o1fi32.svg" alt="[\ispecialfonts{\sfi g}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.163742pt;"/> into the left-handed screw rotation <img src="/teximages/acch1o3/acch1o3fi601.svg" alt="[\ispecialfonts{\sfi g}'{:}\ {-}y, x+1/2, z-1/4 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>, and one might suspect that <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> is a space group of the same affine type but of a different crystallographic space-group type as <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. However, this is not the case because conjugating <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by the translation <img src="/teximages/acch1o3/acch1o3fi605.svg" alt="[\ispecialfonts{\sfi n} = t(0,1/2,0)]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> conjugates <img src="/teximages/acch1o1/acch1o1fi32.svg" alt="[\ispecialfonts{\sfi g}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.163742pt;"/> to <img src="/teximages/acch1o3/acch1o3fi607.svg" alt="[\ispecialfonts{\sfi g}'' = {\sfi n} {\sfi g} {\sfi n}^{-1}{:}\ {-}y+1/2,]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988793pt;"/> <img src="/teximages/acch1o3/acch1o3fi608.svg" alt="[x+1, z+1/4 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>. One sees that <img src="/teximages/acch1o1/acch1o1fi172.svg" alt="[\ispecialfonts{\sfi g}'']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.163742pt;"/> is the composition of <img src="/teximages/acch1o3/acch1o3fi610.svg" alt="[\ispecialfonts{\sfi g}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.163742pt;"/> with the centring translation <img src="/teximages/acpre6/acpre6fi97.svg" alt="[\ispecialfonts{\sfi t}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.228284999999996pt;"/> and hence <img src="/teximages/acch1o3/acch1o3fi612.svg" alt="[\ispecialfonts{\sfi g}'' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.163742pt;"/> belongs to <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/>. This shows that conjugating <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by either the reflection <img src="/teximages/acch1o3/acch1o3fi598.svg" alt="[\ispecialfonts{\sfi m}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> or the translation <img src="/teximages/acch1o3/acch1o3fi616.svg" alt="[\ispecialfonts{\sfi n} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> both result in the same group <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/>. This can also be concluded directly from the space-group diagrams in Fig. 1.3.4.2<figr id="fig1o3o4o2" loc="float"/>. Reflecting in the plane <span class="it"><i>z</i></span> = 0 turns the diagram on the left into the diagram on the right, but the same effect is obtained when the left diagram is shifted by <img src="/teximages/acch1o3/acch1o3fi618.svg" alt="[\textstyle{{1}\over{2}}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> along either <span class="b"><b>a</b></span> or <span class="b"><b>b</b></span>.</p>
<figplace id="fig1o3o4o2"/>
<p>The groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> thus belong to the same crystallographic space-group type because <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is transformed to <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> by a shift of the origin by <img src="/teximages/acch1o3/acch1o3fi623.svg" alt="[\textstyle{{1}\over{2}} {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, which is clearly an orientation-preserving coordinate transformation.</p>
</enun>
<p>
</p>
<p><span class="it"><i>Enantiomorphism</i></span><indexg><index type="s" significance="standard" id="acch1o3index00106">enantiomorphism</index></indexg></p>
<p>The 219 affine space-group types in dimension 3 result in 230 crystallographic space-group types. Since an affine type either forms a single space-group type (in the case where the group obtained by an orientation-reversing coordinate transformation can also be obtained by an orientation-preserving transformation) or splits into two space-group types, this means that there are 11 affine space-group types such that an orientation-reversing coordinate transformation cannot be compensated by an orientation-preserving transformation.</p>
<p>Groups that differ only by their handedness are closely related to each other and share many properties. One addresses this phenomenon by the concept of <span class="it"><i>enantiomorphism</i></span>.</p>
<enun id="example1o3o4o1o6" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Example</st>
<p>Let <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> be a space group of type <img src="/teximages/acch1o2/acch1o2fi283.svg" alt="[P4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (76) generated by a fourfold right-handed screw rotation <img src="/teximages/acch1o3/acch1o3fi626.svg" alt="[(4^+_{001}, (0,0,1/4)) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.06668pt;"/> and the translations of a primitive tetragonal lattice. Then transforming the coordinate system by a reflection in the plane <span class="it"><i>z</i></span> = 0 results in a space group <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> with fourfold left-handed screw rotation <img src="/teximages/acch1o3/acch1o3fi628.svg" alt="[(4^-_{001}, (0,0,1/4)) = (4^+_{001}, (0,0,-1/4))^{-1}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.066681pt;"/>. The groups <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> are isomorphic because they are conjugate by an affine mapping, but <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> belongs to a different space-group type, namely <img src="/teximages/acch1o3/acch1o3fi632.svg" alt="[P4_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/> (78), because <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> does not contain a fourfold left-handed screw rotation with translation part <img src="/teximages/acch1o3/acch1o3fi634.svg" alt="[\textstyle{{1}\over{4}} {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>.</p>
</enun>
<p>
</p>
<enun id="definition1o3o4o1o7" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Definition</st>
<p>Two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> are said to form an <span class="it"><i>enantiomorphic pair</i></span> if they are conjugate under an affine mapping, but not under an orientation-preserving affine mapping.</p>
<p>If <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is the group of isometries of some crystal pattern, then its enantiomorphic counterpart <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> is the group of isometries of the mirror image of this crystal pattern.</p>
</enun>
<p>
</p>
<p>The splitting of affine space-group types of three-dimensional space groups into pairs of crystallographic space-group types gives rise to the following 11 enantiomorphic pairs of space-group types: <img src="/teximages/acch1o3/acch1o3fi639.svg" alt="[P4_1 / P4_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (76/78), <img src="/teximages/acch1o3/acch1o3fi640.svg" alt="[P4_122 / P4_322]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (91/95), <img src="/teximages/acch1o3/acch1o3fi641.svg" alt="[P4_12_12 / P4_32_12]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (92/96), <img src="/teximages/acch1o3/acch1o3fi642.svg" alt="[P3_1 / P3_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (144/145), <img src="/teximages/acch1o3/acch1o3fi643.svg" alt="[P3_112 / P3_212]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (151/153), <img src="/teximages/acch1o3/acch1o3fi644.svg" alt="[P3_121 / P3_221]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (152/154), <img src="/teximages/acch1o3/acch1o3fi645.svg" alt="[P6_1 / P6_5]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (169/173), <img src="/teximages/acch1o3/acch1o3fi646.svg" alt="[P6_2/ P6_4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (170/172), <img src="/teximages/acch1o3/acch1o3fi647.svg" alt="[P6_122 / P6_522]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (178/179), <img src="/teximages/acch1o3/acch1o3fi648.svg" alt="[P6_222 / P6_422]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (180/181), <img src="/teximages/acch1o3/acch1o3fi649.svg" alt="[P4_332 / P4_132]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (212/213). These groups are easily recognized by their Hermann&#8211;Mauguin symbols, because they are the primitive groups for which the Hermann&#8211;Mauguin symbol contains one of the screw rotations <img src="/teximages/acch1o3/acch1o3fi650.svg" alt="[3_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <img src="/teximages/acch1o3/acch1o3fi651.svg" alt="[3_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <img src="/teximages/acch1o3/acch1o3fi652.svg" alt="[4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <img src="/teximages/acch1o3/acch1o3fi653.svg" alt="[4_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>, <img src="/teximages/acch1o3/acch1o3fi654.svg" alt="[6_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <img src="/teximages/acch1o3/acch1o3fi655.svg" alt="[6_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <img src="/teximages/acch1o3/acch1o3fi656.svg" alt="[6_4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> or <img src="/teximages/acch1o3/acch1o3fi657.svg" alt="[6_5]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>. The groups with fourfold screw rotations and body-centred lattices do not give rise to enantiomorphic pairs, because in these groups the orientation reversal can be compensated by an origin shift, as illustrated in the example above for the group of type <img src="/teximages/acch1o3/acch1o3fi592.svg" alt="[I4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>.</p>
<enun id="example1o3o4o1o8" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o1" secnum="enun1.3.4.1">Example</st>
<p>A well known example of a crystal that occurs in forms whose symmetry is described by enantiomorphic pairs of space groups is quartz. For low-temperature &#945;-quartz there exists a left-handed and a right-handed form with space groups <img src="/teximages/acch1o3/acch1o3fi659.svg" alt="[P3_121]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (152) and <img src="/teximages/acch1o3/acch1o3fi660.svg" alt="[P3_221]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (154), respectively. The two individuals of opposite chirality occur together in the so-called Brazil twin of quartz. At higher temperatures, a phase transition leads to the higher-symmetry &#946;-quartz forms, with space groups <img src="/teximages/acch1o3/acch1o3fi661.svg" alt="[P6_422]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (181) and <img src="/teximages/acch1o3/acch1o3fi662.svg" alt="[P6_222]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (180), which still form an enantiomorphic pair.</p>
</enun>
<p>
</p>
</div>

<div id="divsec1o3o4o2" class="sec2" secnum="1.3.4.2" fpage="33" lpage="34">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o2"><tree level="2"/></a>1.3.4.2. Geometric crystal classes<indexg><index significance="standard" id="acch1o3index00107" type="s">geometric crystal class</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o2.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o2" secnum="1.3.4.2">Geometric crystal classes<indexg><index significance="standard" id="acch1o3index00107" type="s">geometric crystal class</index></indexg></st>
<p>We recall that the point group of a space group is the group of linear parts occurring in the space group. Once a basis for the underlying vector space is chosen, such a point group is a group of 3 &#215; 3 matrices. A point group is characterized by the relative positions between the rotation and rotoinversion axes and the reflection planes of the operations it contains, and in this sense a point group is independent of the chosen basis. However, a suitable choice of basis is useful to highlight the geometric properties of a point group.</p>
<enun id="example1o3o4o2o1" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o2" secnum="enun1.3.4.2">Example</st>
<p>A point group of type 3<span class="it"><i>m</i></span> is generated by a threefold rotation and a reflection in a plane with normal vector perpendicular to the rotation axis. Choosing a basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> such that <span class="b"><b>c</b></span> is along the rotation axis, <span class="b"><b>a</b></span> is perpendicular to the reflection plane and <span class="b"><b>b</b></span> is the image of <span class="b"><b>a</b></span> under the threefold rotation (<span class="it"><i>i.e.</i></span> <span class="b"><b>b</b></span> lies in the plane perpendicular to the rotation axis and makes an angle of 120&#176; with <span class="b"><b>a</b></span>), the matrices of the threefold rotation and the reflection with respect to this basis are<span class="fd"><a name="fdu28"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd54.svg" alt="[\pmatrix{ 0 &amp; -1 &amp; 0 \cr 1 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } \ {\rm and} \ \pmatrix{ -1 &amp; 1 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 218px;"/></span></p>
<p>A different useful basis is obtained by choosing a vector <img src="/teximages/acch1o3/acch1o3fi52.svg" alt="[{\bf a}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> in the reflection plane but neither along the rotation axis nor perpendicular to it and taking <img src="/teximages/abch4o3/abch4o3fi270.svg" alt="[{\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> and <img src="/teximages/abch4o3/abch4o3fi274.svg" alt="[{\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> to be the images of <img src="/teximages/abch4o3/abch4o3fi269.svg" alt="[{\bf a}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> under the threefold rotation and its square. Then the matrices of the threefold rotation and the reflection with respect to the basis <img src="/teximages/acch1o3/acch1o3fi668.svg" alt="[{\bf a}', {\bf b}', {\bf c}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> are<span class="fd"><a name="fdu29"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd55.svg" alt="[\pmatrix{ 0 &amp; 0 &amp; 1 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 }\ {\rm and}\ \pmatrix{ 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 \cr 0 &amp; 1 &amp; 0 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 195px;"/></span></p>
</enun>
<p>
</p>
<p>Different choices of a basis for a point group in general result in different matrix groups, and it is natural to consider two point groups as equivalent if they are transformed into each other by a basis transformation. This is entirely analogous to the situation of space groups, where space groups that only differ by the choice of coordinate system are regarded as equivalent. This notion of equivalence is applied at both the level of space groups and point groups.</p>
<enun id="definition1o3o4o2o2" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o2" secnum="enun1.3.4.2">Definition</st>
<p>Two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> with point groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/>, respectively, are said to belong to the same <span class="it"><i>geometric crystal class</i></span> if <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi674.svg" alt="[{\cal P}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> become the same matrix group once suitable bases for the three-dimensional space are chosen.</p>
<p>Equivalently, <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> belong to the same geometric crystal class if the point group <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> can be obtained from <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> by a basis transformation of the underlying vector space <img src="/teximages/acpre6/acpre6fi6.svg" alt="[{\bb V}^3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.227149000000001pt;"/>, <span class="it"><i>i.e.</i></span> if there is an invertible 3 &#215; 3 matrix <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> such that <span class="fd"><a name="fdu1o3o4o2"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd56.svg" alt="[ {\cal P}' = \{ {\bi P}^{-1} {\bi W} {\bi P} \mid {\bi W} \in {\cal P} \}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 152px;"/></span></p>
<p>Also, two matrix groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> are said to belong to the same geometric crystal class if they are conjugate by an invertible 3 &#215; 3 matrix <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
</enun>
<p>
</p>
<p>Historically, the geometric crystal classes in dimension 3 were determined much earlier than the space groups. They were obtained as the symmetry groups for the set of normal vectors of crystal faces which describe the morphological symmetry of crystals.</p>
<p>Note that for the geometric crystal classes in dimension 3 (and in all other odd dimensions) the distinction between orientation-preserving and orientation-reversing transformations is irrelevant, since any conjugation by an arbitrary transformation can already be realized by an orientation-preserving transformation. This is due to the fact that the inversion <img src="/teximages/acch1o3/acch1o3fi684.svg" alt="[-{\bi I}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> on the one hand commutes with every matrix <span class="b"><b><span class="it"><i>W</i></span></b></span>, <span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi685.svg" alt="[(-{\bi I}) {\bi W} = {\bi W} (-{\bi I}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>, and on the other hand <img src="/teximages/acch1o3/acch1o3fi686.svg" alt="[\det(-{\bi I}) = -1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;"/>. If <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is orientation reversing, one has <img src="/teximages/acch1o3/acch1o3fi688.svg" alt="[\det {\bi P} \,\lt\, 0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478206999999996pt;"/> and then <img src="/teximages/acch1o3/acch1o3fi689.svg" alt="[(-{\bi I}) {\bi P} = -{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> is orientation preserving because <img src="/teximages/acch1o3/acch1o3fi690.svg" alt="[\det(-{\bi P}) = -\det {\bi P}\,\gt\, 0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;"/>. But <img src="/teximages/acch1o3/acch1o3fi691.svg" alt="[(-{\bi P})^{-1} {\bi W} (-{\bi P}) = {\bi P}^{-1} {\bi W} {\bi P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>, hence the transformations by <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and <img src="/teximages/acch1o3/acch1o3fi693.svg" alt="[-{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> give the same result and one of <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and <img src="/teximages/acch1o3/acch1o3fi693.svg" alt="[-{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is orientation preserving.</p>
<p><span class="it"><i>Remark</i></span>: One often speaks of the geometric crystal classes as the <span class="it"><i>types of point groups</i></span>. This emphasizes the point of view in which a point group is regarded as the group of linear parts of a space group, written with respect to an <span class="it"><i>arbitrary basis</i></span> of <img src="/teximages/acch1o1/acch1o1fi716.svg" alt="[{\bb R}^n]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 15px;"/> (not necessarily a lattice basis).</p>
<p>It is also common to state that <span class="it"><i>there are 32 point groups in three-dimensional space</i></span>. This is just as imprecise as saying that <span class="it"><i>there are 230 space groups</i></span>, since there are in fact infinitely many point groups and space groups.</p>
<p>What is meant when we say that two space groups have <span class="it"><i>the same point group</i></span> is usually that their point groups are of the same type (<span class="it"><i>i.e.</i></span> lie in the same geometric crystal class) and can thus be <span class="it"><i>made to coincide</i></span> by a suitable basis transformation.</p>
<enun id="example1o3o4o2o3" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o2" secnum="enun1.3.4.2">Example</st>
<p>In the space group <span class="it"><i>P</i></span>3 the threefold rotation generating the point group is given by the matrix<span class="fd"><a name="fdu30"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd57.svg" alt="[{\bi W} = \pmatrix{ 0 &amp; -1 &amp; 0 \cr 1 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; 1 },]" class="mathimage" style="max-width: 100%; height: auto; width: 126px;"/></span>whereas in the space group <span class="it"><i>R</i></span>3 (in the rhombohedral setting) the threefold rotation is given by the matrix<span class="fd"><a name="fdu31"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd58.svg" alt="[{\bi W}' = \pmatrix{ 0 &amp; 0 &amp; 1 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 118px;"/></span>These two matrices are conjugate by the basis transformation<span class="fd"><a name="fdu32"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd59.svg" alt="[{\bi P} = {{1}\over{3}} \pmatrix{ 1 &amp; 0 &amp; -1 \cr 0 &amp; 1 &amp; -1 \cr 1 &amp; 1 &amp; 1 } ,]" class="mathimage" style="max-width: 100%; height: auto; width: 136px;"/></span>which transforms the basis of the hexagonal setting into that of the rhombohedral setting. This shows that the space groups <span class="it"><i>P</i></span>3 and <span class="it"><i>R</i></span>3 belong to the same geometric crystal class.</p>
</enun>
<p>
</p>
<p>The example is typical in the sense that different groups in the same geometric crystal class usually describe the same group of linear parts acting on different lattices, <span class="it"><i>e.g.</i></span> primitive and centred. Writing the action of the linear parts with respect to primitive bases of different lattices gives rise to different matrix groups.</p>
</div>

<div id="divsec1o3o4o3" class="sec2" secnum="1.3.4.3" fpage="34" lpage="37">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o3"><tree level="2"/></a>1.3.4.3. Bravais types of lattices and Bravais classes<indexg><index type="s" significance="standard" id="acch1o3index00108">Bravais type of lattice</index><index significance="standard" id="acch1o3index00109" type="s">Bravais class</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o3.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o3" secnum="1.3.4.3">Bravais types of lattices and Bravais classes<indexg><index type="s" significance="standard" id="acch1o3index00108">Bravais type of lattice</index><index significance="standard" id="acch1o3index00109" type="s">Bravais class</index></indexg></st>
<p>In the classification of space groups into geometric crystal classes, only the point-group part is considered and the translation lattice is ignored. It is natural that the converse point of view is also adopted, where space groups are grouped together according to their translation lattices, irrespective of what the point groups are.</p>
<p>We have already seen that a lattice can be characterized by its metric tensor, containing the scalar products of a primitive basis. If a point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> acts on a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, it fixes the metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, <span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi409.svg" alt="[{\bi W}^{\rm T} \cdot {\bi G} \cdot {\bi W} = {\bi G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999997pt;"/> for all <img src="/teximages/acch1o2/acch1o2fi108.svg" alt="[{\bi W}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389999999996pt;"/> in <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and is thus a subgroup of the Bravais group <img src="/teximages/acch1o3/acch1o3fi704.svg" alt="[Aut({\bf L})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Also, a matrix group <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> is called a <span class="it"><i>Bravais group</i></span><indexg><index type="s" significance="standard" id="acch1o3index00110">Bravais group</index></indexg> if it is the Bravais group <img src="/teximages/acch1o3/acch1o3fi704.svg" alt="[Aut({\bf L})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> for some lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. The Bravais groups govern the classification of lattices.</p>
<enun id="definition1o3o4o3o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Definition</st>
<p>Two lattices <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> belong to the same <span class="it"><i>Bravais type of lattices</i></span> if their Bravais groups <img src="/teximages/acch1o3/acch1o3fi704.svg" alt="[Aut({\bf L})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> and <img src="/teximages/acch1o3/acch1o3fi712.svg" alt="[Aut({\bf L}')]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;"/> are the same matrix group when written with respect to suitable primitive bases of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/>.</p>
</enun>
<p>
</p>
<p>Note that in order to have the same Bravais group, the metric tensors of the two lattices <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> do not have to be the same or scalings of each other.</p>
<enun id="example1o3o4o3o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Example</st>
<p>The mineral rutile (TiO<span class="inf"><sub>2</sub></span>) has a space group of type <img src="/teximages/acch1o3/acch1o3fi717.svg" alt="[P4_2/mnm]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> (136) with a primitive tetragonal cell with cell parameters <span class="it"><i>a</i></span> = <span class="it"><i>b</i></span> = 4.594&#8197;&#197; and <span class="it"><i>c</i></span> = 2.959&#8197;&#197;. The metric tensor of the translation lattice <span class="b"><b>L</b></span> is therefore<span class="fd"><a name="fdu33"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd60.svg" alt="[{\bi G} = \pmatrix{ 4.594^2 &amp; 0 &amp; 0 \cr 0 &amp; 4.594^2 &amp; 0 \cr 0 &amp; 0 &amp; 2.959^2 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 201px;"/></span>and the Bravais group of the lattice is generated by the fourfold rotation<span class="fd"><a name="fdu34"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd61.svg" alt="[\pmatrix{ 0 &amp; -1 &amp; 0 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 85px;"/></span>around the <span class="it"><i>z</i></span> axis, the reflection<span class="fd"><a name="fdu35"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd62.svg" alt="[\pmatrix{ -1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 85px;"/></span>in the plane <span class="it"><i>x</i></span> = 0 and the reflection<span class="fd"><a name="fdu36"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd63.svg" alt="[\pmatrix{ 1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; -1 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 85px;"/></span>in the plane <span class="it"><i>z</i></span> = 0.</p>
<p>The silicate mineral cristobalite also has (at low temperatures) a primitive tetragonal cell with <span class="it"><i>a</i></span> = <span class="it"><i>b</i></span> = 4.971&#8197;&#197; and <span class="it"><i>c</i></span> = 6.928&#8197;&#197;, and the space-group type is <img src="/teximages/acch1o3/acch1o3fi718.svg" alt="[P4_12_12]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> (92). In this case the metric tensor of the translation lattice <img src="/teximages/acch1o3/acch1o3fi719.svg" alt="[{\bf L}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is<span class="fd"><a name="fdu37"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd64.svg" alt="[{\bi G}' = \pmatrix{ 4.971^2 &amp; 0 &amp; 0 \cr 0 &amp; 4.971^2 &amp; 0 \cr 0 &amp; 0 &amp; 6.928^2 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 203px;"/></span>and one checks that the Bravais group of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is precisely the same as that of <span class="b"><b>L</b></span>. Therefore, the translation lattices <span class="b"><b>L</b></span> for rutile and <img src="/teximages/acch1o3/acch1o3fi719.svg" alt="[{\bf L}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> for cristobalite belong to the same Bravais type of lattices.</p>
</enun>
<p>
</p>
<p>The different Bravais types of lattices, their cell parameters and metric tensors are displayed in <related volume="A" revision="c" chnum="3.1" url="/Ac/ch3o1v0001/#table3o1o2o1"><relchtitle>Crystal lattices</relchtitle><relau>H. Burzlaff</relau><relau>H. Grimmer</relau><relau>B. Gruber</relau><relau>P. M. de Wolff</relau><relau>H. Zimmermann</relau></related>Tables 3.1.2.1<a href="/Ac/ch3o1v0001/#table3o1o2o1"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 (dimension 2) and <related volume="A" revision="c" chnum="3.1" url="/Ac/ch3o1v0001/#table3o1o2o2"><relchtitle>Crystal lattices</relchtitle><relau>H. Burzlaff</relau><relau>H. Grimmer</relau><relau>B. Gruber</relau><relau>P. M. de Wolff</relau><relau>H. Zimmermann</relau></related>3.1.2.2<a href="/Ac/ch3o1v0001/#table3o1o2o2"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 (dimension 3): in dimension 2 there are 5 Bravais types and in dimension 3 there are 14 Bravais types of lattices.</p>
<p>It is crucial for the classification of lattices <span class="it"><i>via</i></span> their Bravais groups that one works with primitive bases, because a primitive and a body-centred cubic lattice have the same automorphisms when written with respect to the conventional cubic basis, but are clearly different types of lattices.</p>
<enun id="example1o3o4o3o3" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Example</st>
<p>The silicate mineral zircon (ZrSiO<span class="inf"><sub>4</sub></span>) has a body-centred tetragonal cell with cell parameters <span class="it"><i>a</i></span> = <span class="it"><i>b</i></span> = 6.607&#8197;&#197; and <span class="it"><i>c</i></span> = 5.982&#8197;&#197;. The body-centred translation lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is spanned by the primitive tetragonal lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with <img src="/teximages/acch1o3/acch1o3fi725.svg" alt="[\alpha = \beta = \gamma = 90^\circ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.570362pt;"/> and the centring vector <img src="/teximages/acch1o3/acch1o3fi726.svg" alt="[{\bf v} = \textstyle{{1}\over{2}} ({\bf a} + {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>. A primitive basis of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is obtained as <img src="/teximages/acch1o3/acch1o3fi75.svg" alt="[({\bf a}', {\bf b}', {\bf c}') = ({\bf a}, {\bf b}, {\bf c}) {\bi P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> with<span class="fd"><a name="fdu38"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd65.svg" alt="[{\bi P} = {{1}\over{2}} \pmatrix{ -1 &amp; 1 &amp; 1 \cr 1 &amp; -1 &amp; 1 \cr 1 &amp; 1 &amp; -1 } ,]" class="mathimage" style="max-width: 100%; height: auto; width: 160px;"/></span><span class="it"><i>i.e.</i></span> <img src="/teximages/acch1o3/acch1o3fi729.svg" alt="[{\bf a}' = \textstyle{{1}\over{2}} (-{\bf a} + {\bf b} + {\bf c}) = -{\bf a} + {\bf v} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi730.svg" alt="[{\bf b}' = \textstyle{{1}\over{2}} ({\bf a} - {\bf b} + {\bf c}) = -{\bf b} + {\bf v} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>, <img src="/teximages/acch1o3/acch1o3fi731.svg" alt="[{\bf c}' = \textstyle{{1}\over{2}} ({\bf a} + {\bf b} - {\bf c}) = -{\bf c} + {\bf v} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/> and the metric tensor <img src="/teximages/acch1o3/acch1o3fi105.svg" alt="[{\bi G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389000000001pt;"/> of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> with respect to the primitive basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> is <span class="fd"><a name="fdu1o3o4o3"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd66.svg" alt="[ \eqalign{{\bi G}' &amp;= {\bi P}^{\rm T} \pmatrix{ 6.607^2 &amp; 0 &amp; 0 \cr 0 &amp; 6.607^2 &amp; 0 \cr 0 &amp; 0 &amp; 5.982^2 } {\bi P} \cr&amp;= \pmatrix{ 5.547^2 &amp; -12.880 &amp; -8.946 \cr -12.880 &amp; 5.547^2 &amp; -8.946 \cr -8.946 &amp; -8.946 &amp; 5.547^2 }. }]" class="mathimage" style="max-width: 100%; height: auto; width: 245px;"/></span>The Bravais group of the primitive tetragonal lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is generated (as in the previous example) by<span class="fd"><a name="fdu39"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd67.svg" alt="[\displaylines{{\bi W}_1 = \pmatrix{ 0 &amp; -1 &amp; 0 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 },\quad {\bi W}_2 = \pmatrix{ -1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } \cr {\rm and} \ {\bi W}_3 = \pmatrix{ 1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; -1 } ,}]" class="mathimage" style="max-width: 100%; height: auto; width: 272px;"/></span>and these matrices also generate the Bravais group of the body-centred tetragonal lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/>, but written with respect to the primitive basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> these matrices are transformed to<span class="fd"><a name="fdu40"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd68.svg" alt="[\eqalign{{\bi W}_1' &amp;= {\bi P}^{-1} {\bi W}_1 {\bi P} = \pmatrix{ 0 &amp; 1 &amp; 0 \cr 0 &amp; 1 &amp; -1 \cr -1 &amp; 1 &amp; 0 } ,\cr {\bi W}_2' &amp;= {\bi P}^{-1} {\bi W}_2 {\bi P} = \pmatrix{ 1 &amp; 0 &amp; 0 \cr 1 &amp; 0 &amp; -1 \cr 1 &amp; -1 &amp; 0 }\ {\rm and}\cr {\bi W}_3' &amp;= {\bi P}^{-1} {\bi W}_3 {\bi P} = \pmatrix{ 0 &amp; -1 &amp; 1 \cr -1 &amp; 0 &amp; 1 \cr 0 &amp; 0 &amp; 1 } .}]" class="mathimage" style="max-width: 100%; height: auto; width: 233px;"/></span></p>
<p>That the primitive and the body-centred tetragonal lattices have different types ultimately follows from the fact that the body-centred lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> does not have a primitive basis consisting of vectors <img src="/teximages/acch1o3/acch1o3fi739.svg" alt="[{\bf a}'', {\bf b}'', {\bf c}'' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> which are pairwise perpendicular and such that <img src="/teximages/abch13o2/abch13o2fi13.svg" alt="[{\bf a}'']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> and <img src="/teximages/abch13o2/abch13o2fi14.svg" alt="[{\bf b}'']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> have the same length. This would be required to have the matrices <img src="/teximages/acch1o3/acch1o3fi742.svg" alt="[{\bi W}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/>, <img src="/teximages/acch1o3/acch1o3fi743.svg" alt="[{\bi W}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi744.svg" alt="[{\bi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/> in the Bravais group of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/>.</p>
</enun>
<p>
</p>
<p>As we have seen, the metric tensors of lattices belonging to the same Bravais type need not be the same, but if they are written with respect to suitable bases they are found to have the same structure, differing only in the specific values for certain free parameters.</p>
<enun id="definition1o3o4o3o4" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Definition</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> be a lattice with metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> with respect to a primitive basis and let <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> = <img src="/teximages/acch1o3/acch1o3fi704.svg" alt="[Aut({\bf L})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> = <img src="/teximages/acch1o3/acch1o3fi750.svg" alt="[ \{ {\bi W} \in {\rm GL}_3({\bb Z}) \mid {\bi W}^{\rm T} \cdot {\bi G} \cdot {\bi W} = {\bi G} \} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> be the Bravais group of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Then <span class="fd"><a name="fdu1o3o4o4"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd69.svg" alt="[\displaylines{ {\bf M}({\cal B}): = \{ {\bi G}' \ {\rm symmetric\ 3 \times 3\ matrix} \mid\hfill\cr\hfill {\bi W}^{\rm T} \cdot {\bi G}' \cdot {\bi W} = {\bi G}' \ {\rm for\ all }\ {\bi W} \in {\cal B} \} }]" class="mathimage" style="max-width: 100%; height: auto; width: 448px;"/></span>is called the <span class="it"><i>space of metric tensors</i></span> of <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/>. The dimension of <img src="/teximages/acch1o3/acch1o3fi753.svg" alt="[{\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> is called the <span class="it"><i>number of free parameters</i></span> of the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
<p>Analogously, for an arbitrary integral matrix group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>, <span class="fd"><a name="fdu1o3o4o5"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd70.svg" alt="[\displaylines{\quad{\bf M}({\cal P}): = \{ {\bi G}'\ {\rm symmetric\ 3 \times 3\ matrix} \mid \hfill\cr\hfill{\bi W}^{\rm T} \cdot {\bi G}' \cdot {\bi W} = {\bi G}' \ {\rm for\ all }\ {\bi W} \in {\cal P} \} }]" class="mathimage" style="max-width: 100%; height: auto; width: 433px;"/></span>is called the <span class="it"><i>space of metric tensors</i></span> of <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>. If <img src="/teximages/acch1o3/acch1o3fi757.svg" alt="[\dim {\bf M}({\cal P}')]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;"/> = <img src="/teximages/acch1o3/acch1o3fi758.svg" alt="[\dim {\bf M}({\cal P})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> for a subgroup <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> of <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>, the spaces of metric tensors are the same for both groups and one says that <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> <span class="it"><i>does not act on a more general lattice</i></span> than <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> does.</p>
</enun>
<p>
</p>
<p>It is clear that <img src="/teximages/acch1o3/acch1o3fi753.svg" alt="[{\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> contains in particular the metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> of the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> of which <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> is the Bravais group. Moreover, <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> is a subgroup of the Bravais group of every lattice with metric tensor in <img src="/teximages/acch1o3/acch1o3fi768.svg" alt="[{\bf M}({\cal B}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>.</p>
<enun id="example1o3o4o3o5" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Example</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> be a lattice with metric tensor<span class="fd"><a name="fdu41"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd71.svg" alt="[\pmatrix{ 17 &amp; 0 &amp; 0 \cr 0 &amp; 17 &amp; 0 \cr 0 &amp; 0 &amp; 42 } ,]" class="mathimage" style="max-width: 100%; height: auto; width: 104px;"/></span>then <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is a tetragonal lattice with Bravais group <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> of type 4/<span class="it"><i>mmm</i></span> generated by the fourfold rotation<span class="fd"><a name="fdu42"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd72.svg" alt="[{\bi W}_1 = \pmatrix{ 0 &amp; -1 &amp; 0 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 122px;"/></span>and the reflections<span class="fd"><a name="fdu43"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd73.svg" alt="[{\bi W}_2 = \pmatrix{ -1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } \ {\rm and}\ {\bi W}_3 = \pmatrix{ 1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; -1 }.]" class="mathimage" style="max-width: 100%; height: auto; width: 288px;"/></span>The space of metric tensors of <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> is <span class="fd"><a name="fdu1o3o4o6"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd74.svg" alt="[ {\bf M}({\cal B}) = \left\{ \pmatrix{ g_{11} &amp; 0 &amp; 0 \cr 0 &amp; g_{11} &amp; 0 \cr 0 &amp; 0 &amp; g_{33} } \mid g_{11},g_{33} \in {\bb R} \right\} ]" class="mathimage" style="max-width: 100%; height: auto; width: 266px;"/></span>and the number of free parameters of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> is 2. </p>
<p>For every lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> with metric tensor <img src="/teximages/acch1o3/acch1o3fi105.svg" alt="[{\bi G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389000000001pt;"/> in <img src="/teximages/acch1o3/acch1o3fi753.svg" alt="[{\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> such that <img src="/teximages/acch1o3/acch1o3fi777.svg" alt="[g_{11} \neq g_{33}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.582317pt;"/>, one can check that the Bravais group of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is equal to <img src="/teximages/acch1o3/acch1o3fi779.svg" alt="[{\cal B} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/>, hence these lattices belong to the same Bravais type of lattices as <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. On the other hand, if it happens that <img src="/teximages/acch1o3/acch1o3fi781.svg" alt="[g_{11} = g_{33}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> in the metric tensor <img src="/teximages/acch1o3/acch1o3fi105.svg" alt="[{\bi G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214389000000001pt;"/> of a lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/>, then the Bravais group of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is the full cubic point group of type <img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/> and <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> is a proper subgroup of the Bravais group of <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/>. In this case the lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> is of a different Bravais type to <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, namely cubic.</p>
<p>The subgroup <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> generated only by the fourfold rotation <img src="/teximages/acch1o3/acch1o3fi742.svg" alt="[{\bi W}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> has the same space of metric tensors as <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/>, thus this subgroup acts on the same types of lattices as <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> (<span class="it"><i>i.e.</i></span> tetragonal lattices). On the other hand, for the subgroup <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> of <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> generated by the reflections <img src="/teximages/acch1o3/acch1o3fi797.svg" alt="[{\bi W}_2 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi744.svg" alt="[{\bi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/>, the space of metric tensors is <span class="fd"><a name="fdu1o3o4o7"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd75.svg" alt="[ {\bf M}({\cal P}') = \left\{ \pmatrix{ g_{11} &amp; 0 &amp; 0 \cr 0 &amp; g_{22} &amp; 0 \cr 0 &amp; 0 &amp; g_{33} } \mid g_{11}, g_{22}, g_{33} \in {\bb R} \right\} ]" class="mathimage" style="max-width: 100%; height: auto; width: 296px;"/></span>and is thus of dimension 3. This shows that the subgroup <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> acts on more general lattices than <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/>, namely on orthorhombic lattices.</p>
</enun>
<p>
</p>
<p><span class="it"><i>Remark</i></span>: The metric tensor of a lattice basis is a <span class="it"><i>positive definite</i></span><fnr id="fn2" number="2"/> matrix. It is clear that not all matrices in <img src="/teximages/acch1o3/acch1o3fi753.svg" alt="[{\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> are positive definite [if <img src="/teximages/acch1o3/acch1o3fi805.svg" alt="[{\bi G} \in {\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> is positive definite, then <img src="/teximages/acch1o3/acch1o3fi806.svg" alt="[-{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> is certainly not positive definite], but the different geometries of lattices on which <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;"/> acts are represented precisely by the positive definite metric tensors in <img src="/teximages/acch1o3/acch1o3fi753.svg" alt="[{\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/>.</p>
<p>The space of metric tensors obtained from a lattice can be interpreted as an expression of the metric tensor with general entries, <span class="it"><i>i.e.</i></span> as a generic metric tensor describing the different lattices within the same Bravais type. Special choices for the entries may lead to lattices with accidental higher symmetry, which is in fact a common phenomenon in phase transitions caused by changes of temperature or pressure.</p>
<p>One says that the translation lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> of a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> with point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> has a <span class="it"><i>specialized metric</i></span><indexg><index type="s" id="acch1o3index00111" significance="standard">specialized metrics</index></indexg> if the dimension of the space of metric tensors of <img src="/teximages/acch1o3/acch1o3fi812.svg" alt="[{\cal B} = Aut({\bf L}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> is smaller than the dimension of the space of metric tensors of <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>. Viewed from a slightly different angle, a specialized metric occurs if the location of the atoms within the unit cell reduces the symmetry of the translation lattice to that of a different lattice type.</p>
<enun id="example1o3o4o3o6" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Example</st>
<p>A space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> of type <span class="it"><i>P</i></span>2/<span class="it"><i>m</i></span> (10) with cell parameters <span class="it"><i>a</i></span> = 4.4, <span class="it"><i>b</i></span> = 5.5, <span class="it"><i>c</i></span> = 6.6&#8197;&#197;, <img src="/teximages/acch1o3/acch1o3fi725.svg" alt="[\alpha = \beta = \gamma = 90^\circ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.570362pt;"/> has a specialized metric, because the point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of type 2/<span class="it"><i>m</i></span> is generated by<span class="fd"><a name="fdu44"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd76.svg" alt="[{\bi W} = \pmatrix{ -1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; -1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 129px;"/></span>and <img src="/teximages/acch1o3/acch1o3fi817.svg" alt="[{\bi -I}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, and has<span class="fd"><a name="fdu45"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd77.svg" alt="[{\bf M}({\cal P}) = \left\{ \pmatrix{ g_{11} &amp; 0 &amp; g_{13} \cr 0 &amp; g_{22} &amp; 0 \cr g_{13} &amp; 0 &amp; g_{33} } \mid g_{11}, g_{22}, g_{33}, g_{13} \in {\bb R} \right\} ]" class="mathimage" style="max-width: 100%; height: auto; width: 317px;"/></span>as its space of metric tensors, which is of dimension 4. The lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with the given cell parameters, however, is ortho&#173;rhombic, since the free parameter <img src="/teximages/acch1o3/acch1o3fi819.svg" alt="[g_{13}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/> is specialized to <img src="/teximages/acch1o3/acch1o3fi820.svg" alt="[g_{13} = 0 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;"/>. The automorphism group <img src="/teximages/acch1o3/acch1o3fi704.svg" alt="[Aut({\bf L})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> is of type <span class="it"><i>mmm</i></span> and has a space of metric tensors of dimension 3, namely<span class="fd"><a name="fdu46"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd78.svg" alt="[\left\{ \pmatrix{ g_{11} &amp; 0 &amp; 0 \cr 0 &amp; g_{22} &amp; 0 \cr 0 &amp; 0 &amp; g_{33} } \mid g_{11}, g_{22}, g_{33} \in {\bb R} \right\} .]" class="mathimage" style="max-width: 100%; height: auto; width: 245px;"/></span></p>
<p>The higher symmetry of the translation lattice would, for example, be destroyed by an atomic configuration compatible with the lattice and represented by only two atoms in the unit cell located at 0.17, 1/2, 0.42 and 0.83, 1/2, 0.58. The two atoms are related by a twofold rotation around the <span class="it"><i>b</i></span> axis, which indicates the invariance of the configuration under twofold rotations with axes parallel to <span class="b"><b>b</b></span>, but in contrast to the lattice <span class="b"><b>L</b></span>, the atomic configuration is not compatible with rotations around the <span class="it"><i>a</i></span> or the <span class="it"><i>c</i></span> axes.</p>
</enun>
<p>
</p>
<p>By looking at the spaces of metric tensors, space groups can be classified according to the Bravais types of their translation lattices, without suffering from complications due to specialized metrics.</p>
<enun id="definition1o3o4o3o7" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Definition</st>
<p>Let <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> be a lattice with metric tensor <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;"/> and Bravais group <img src="/teximages/acch1o3/acch1o3fi824.svg" alt="[{\cal B} = Aut({\bf L})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> and let <img src="/teximages/acch1o3/acch1o3fi768.svg" alt="[{\bf M}({\cal B}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> be the space of metric tensors associated to <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. Then those space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> form the <span class="it"><i>Bravais class</i></span> corresponding to the Bravais type of <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> for which <img src="/teximages/acch1o3/acch1o3fi829.svg" alt="[{\bf M}({\cal P}) = {\bf M}({\cal B})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;"/> when the point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> is written with respect to a suitable primitive basis of the translation lattice of <img src="/teximages/acch1o3/acch1o3fi832.svg" alt="[\cal G]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/>. The names for the Bravais classes are the same as those for the corresponding Bravais types of lattices.</p>
</enun>
<p>
</p>
<p>The Bravais groups of lattices provide a link between lattices and point groups, the two building blocks of space groups. However, although the Bravais group of a lattice is simply a matrix group, the fact that it is expressed with respect to a primitive basis and fixes the metric tensor of the lattice preserves the necessary information about the lattice. When the Bravais group is regarded as a point group, the information about the lattice is lost, since point groups can be written with respect to an arbitrary basis. In order to distinguish Bravais groups of lattices at the level of point groups and geometric crystal classes, the concept of a holohedry is introduced.</p>
<enun id="definition1o3o4o3o8" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Definition</st>
<p>The geometric crystal class of a point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> is called a <span class="it"><i>holohedry</i></span><indexg><index significance="standard" id="acch1o3index00112" type="s">holohedry</index></indexg> (or <span class="it"><i>lattice point group</i></span><indexg><index type="s" id="acch1o3index00113" significance="standard">lattice point group</index></indexg>, <span class="it"><i>cf.</i></span> Chapters <related volume="A" revision="c" chnum="3.1" url="/Ac/ch3o1v0001/"><relchtitle>Crystal lattices</relchtitle><relau>H. Burzlaff</relau><relau>H. Grimmer</relau><relau>B. Gruber</relau><relau>P. M. de Wolff</relau><relau>H. Zimmermann</relau></related>3.1<a href="/Ac/ch3o1v0001/"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
 and <related volume="A" revision="c" chnum="3.3" url="/Ac/ch3o3v0001/"><relchtitle>Space-group symbols and their use</relchtitle><relau>H. Burzlaff</relau><relau>H. Zimmermann</relau></related>3.3<a href="/Ac/ch3o3v0001/"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
) if <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> is the Bravais group of some lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
</enun>
<p>
</p>
<enun id="example1o3o4o3o9" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o3" secnum="enun1.3.4.3">Example</st>
<p>Let <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> be the point group of type <img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/> generated by the threefold rotoinversion<span class="fd"><a name="fdu47"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd79.svg" alt="[{\bi W}_1 = \pmatrix{ 0 &amp; 1 &amp; 0 \cr -1 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; -1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 134px;"/></span>around the <span class="it"><i>z</i></span> axis and the twofold rotation<span class="fd"><a name="fdu48"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd80.svg" alt="[{\bi W}_2 = \pmatrix{ 1 &amp; -1 &amp; 0 \cr 0 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; -1 },]" class="mathimage" style="max-width: 100%; height: auto; width: 143px;"/></span>expressed with respect to the conventional basis <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of a hexagonal lattice. The group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> is not the Bravais group of the lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> spanned by <img src="/teximages/acch1o3/acch1o3fi44.svg" alt="[{\bf a}, {\bf b}, {\bf c} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> because this lattice also allows a sixfold rotation around the <span class="it"><i>z</i></span> axis, which is not contained in <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/>. But <img src="/teximages/acch1o3/acch1o3fi395.svg" alt="[{\cal P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> also acts on the rhombohedrally centred lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/> with primitive basis <img src="/teximages/acch1o3/acch1o3fi268.svg" alt="[{\bf a}' = \textstyle{{1}\over{3}} (2 {\bf a} + {\bf b} + {\bf c}) ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>, <img src="/teximages/acch1o3/acch1o3fi269.svg" alt="[{\bf b}' = \textstyle{{1}\over{3}} (-{\bf a} + {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>, <img src="/teximages/acch1o3/acch1o3fi270.svg" alt="[{\bf c}' = \textstyle{{1}\over{3}} (-{\bf a} - 2 {\bf b} + {\bf c})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>. With respect to the basis <img src="/teximages/abch4o3/abch4o3fi213.svg" alt="[{\bf a}', {\bf b}', {\bf c}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> the rotoinversion and twofold rotation are transformed to<span class="fd"><a name="fdu49"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd81.svg" alt="[{\bi W}_1' = \pmatrix{ 0 &amp; 0 &amp; -1 \cr -1 &amp; 0 &amp; 0 \cr 0 &amp; -1 &amp; 0 } \ {\rm and} \ {\bi W}_2' = \pmatrix{ 0 &amp; -1 &amp; 0 \cr -1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; -1 } ,]" class="mathimage" style="max-width: 100%; height: auto; width: 336px;"/></span>and these matrices indeed generate the Bravais group of <img src="/teximages/acch1o3/acch1o3fi719.svg" alt="[{\bf L}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;"/>. The geometric crystal class with symbol <img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;"/> is therefore a holohedry.</p>
</enun>
<p>
</p>
<p>Note that in dimension 3 the above is actually the only example of a geometric crystal class in which the point groups are Bravais groups for some but not for all the lattices on which they act. In all other cases, each matrix group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> corresponding to a holohedry is actually the Bravais group of the lattice spanned by the basis with respect to which <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> is written.</p>
</div>

<div id="divsec1o3o4o4" class="sec2" secnum="1.3.4.4" fpage="37" lpage="41">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o4"><tree level="2"/></a>1.3.4.4. Other classifications of space groups</h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o4.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o4" secnum="1.3.4.4">Other classifications of space groups</st>
<p>In this section we summarize a number of other classification schemes which are perhaps of slightly lower significance than those of space-group types, geometric crystal classes and Bravais types of lattices, but also play an important role for certain applications.</p>

<div id="divsec1o3o4o4o1" class="sec3" secnum="1.3.4.4.1" fpage="37" lpage="39">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o4o1"><tree level="3"/></a>1.3.4.4.1. Arithmetic crystal classes<indexg><index type="s" significance="standard" id="acch1o3index00114">arithmetic crystal class</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o4o1.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o4o1" secnum="1.3.4.4.1">Arithmetic crystal classes<indexg><index type="s" significance="standard" id="acch1o3index00114">arithmetic crystal class</index></indexg></st>
<p>We have already seen that every space group can be assigned to a symmorphic space group in a natural way by setting the translation parts of coset representatives with respect to the translation subgroup to <img src="/teximages/acch1o3/acch1o3fi501.svg" alt="[{\bi o}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.154836999999995pt;"/>. The groups assigned to a symmorphic space group in this way all have the same translation lattice and the same point group but the different possibilities for the interplay between these two parts are ignored.</p>
<p>If we want to collect together all space groups that correspond to symmorphic space groups of the same type, we arrive at the classification into <span class="it"><i>arithmetic crystal classes</i></span>. This can also be seen as a classification of the symmorphic space-group types. The distribution of the space groups into arithmetic classes, represented by the corresponding symmorphic space-group types, is given in <related volume="A" revision="c" chnum="2.1" url="/Ac/ch2o1v0001/#table2o1o3o3"><relchtitle>Guide to the use of the space-group tables</relchtitle><relau>Th. Hahn</relau><relau>A. Looijenga-Vos</relau><relau>M. I. Aroyo</relau><relau>H. D. Flack</relau><relau>K. Momma</relau><relau>P. Konstantinov</relau></related>Table 2.1.3.3<a href="/Ac/ch2o1v0001/#table2o1o3o3"><img align="bottom" border="0" src="/graphics/greenarr.gif" alt="[link]"/></a>
.</p>
<p>The crucial observation for characterizing this classification is that space groups that correspond to the same symmorphic space group all have translation lattices of the same Bravais type. This means that the freedom in the choice of a basis transformation of the underlying vector space is restricted, because a primitive basis has to be mapped again to a primitive basis. Assuming that the point groups are written with respect to primitive bases, this means that the basis transformation is an integral matrix with determinant <img src="/teximages/acch1o3/acch1o3fi136.svg" alt="[\pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>.</p>
<enun id="definition1o3o4o4o1o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o1" secnum="enun1.3.4.4.1">Definition</st>
<p>Two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> with point groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/>, respectively, both written with respect to primitive bases of their translation lattices, are said to lie in the same <span class="it"><i>arithmetic crystal class</i></span> if <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> can be obtained from <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> by an integral basis transformation of determinant <img src="/teximages/acch1o3/acch1o3fi861.svg" alt="[\pm 1 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>, <span class="it"><i>i.e.</i></span> if there is an integral 3 &#215; 3 matrix <img src="/teximages/acch1o3/acch1o3fi862.svg" alt="[{\bi P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with <img src="/teximages/acch1o3/acch1o3fi82.svg" alt="[\det {\bi P} = \pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.119104999999996pt;"/> such that <span class="fd"><a name="fdu1o3o4o8"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd56.svg" alt="[ {\cal P}' = \{ {\bi P}^{-1} {\bi W} {\bi P} \mid {\bi W} \in {\cal P} \}. ]" class="mathimage" style="max-width: 100%; height: auto; width: 152px;"/></span></p>
<p>Also, two integral matrix groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> are said to belong to the same arithmetic crystal class if they are conjugate by an integral 3 &#215; 3 matrix <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> with <img src="/teximages/acch1o3/acch1o3fi867.svg" alt="[\det {\bi P} = \pm 1 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.119104999999996pt;"/>.</p>
</enun>
<p>
</p>
<enun id="example1o3o4o4o1o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o1" secnum="enun1.3.4.4.1">Example</st>
<p>Let<span class="fd"><a name="fdu50"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd83.svg" alt="[\displaylines{{\bi M}_1 = \pmatrix{ -1 &amp; 0 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } ,\quad {\bi M}_2 = \pmatrix{ 1 &amp; 0 &amp; 0 \cr 0 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } \cr {\rm and} \ {\bi M}_3 = \pmatrix{ 0 &amp; 1 &amp; 0 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 } }]" class="mathimage" style="max-width: 100%; height: auto; width: 274px;"/></span>be reflections in the planes <span class="it"><i>x</i></span> = 0, <span class="it"><i>y</i></span> = 0 and <span class="it"><i>x</i></span> = <span class="it"><i>y</i></span>, respectively, and let <img src="/teximages/acch1o3/acch1o3fi868.svg" alt="[{\cal P}_1 = \langle {\bi M}_1 \rangle ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/>, <img src="/teximages/acch1o3/acch1o3fi869.svg" alt="[{\cal P}_2 = \langle {\bi M}_2 \rangle]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> and <img src="/teximages/acch1o3/acch1o3fi870.svg" alt="[{\cal P}_3 = \langle {\bi M}_3 \rangle ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;"/> be the integral matrix groups generated by these reflections. Then <img src="/teximages/acch1o3/acch1o3fi871.svg" alt="[{\cal P}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi872.svg" alt="[{\cal P}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> belong to the same arithmetic crystal class because they are transformed into each other by the basis transformation<span class="fd"><a name="fdu51"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd84.svg" alt="[{\bi P} = \pmatrix{ 0 &amp; 1 &amp; 0 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 }]" class="mathimage" style="max-width: 100%; height: auto; width: 104px;"/></span>interchanging the <span class="it"><i>x</i></span> and <span class="it"><i>y</i></span> axes. But <img src="/teximages/acch1o3/acch1o3fi873.svg" alt="[{\cal P}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904429pt;"/> belongs to a different arithmetic crystal class, because <img src="/teximages/acch1o3/acch1o3fi874.svg" alt="[{\bi M}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/> is not conjugate to <img src="/teximages/acch1o3/acch1o3fi875.svg" alt="[{\bi M}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> by an integral matrix <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> of determinant <img src="/teximages/acch1o3/acch1o3fi136.svg" alt="[\pm 1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/>. The two groups <img src="/teximages/acch1o3/acch1o3fi871.svg" alt="[{\cal P}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi873.svg" alt="[{\cal P}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904429pt;"/> belong, however, to the same geometric crystal class, because <img src="/teximages/acch1o3/acch1o3fi875.svg" alt="[{\bi M}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi874.svg" alt="[{\bi M}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/> are transformed into each other by the basis transformation<span class="fd"><a name="fdu52"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd85.svg" alt="[{\bi P} = \pmatrix{ {{1}\over{2}} &amp; -{{1}\over{2}} &amp; 0 \cr {{1}\over{2}} &amp; {{1}\over{2}} &amp; 0 \cr 0 &amp; 0 &amp; 1 } ,]" class="mathimage" style="max-width: 100%; height: auto; width: 124px;"/></span>which has determinant <img src="/teximages/acch1o3/acch1o3fi618.svg" alt="[\textstyle{{1}\over{2}}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.122616pt;"/>. This basis transformation shows that <img src="/teximages/acch1o3/acch1o3fi875.svg" alt="[{\bi M}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;"/> and <img src="/teximages/acch1o3/acch1o3fi874.svg" alt="[{\bi M}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;"/> can be interpreted as the action of the same reflection on a primitive lattice and on a <span class="it"><i>C</i></span>-centred lattice.</p>
</enun>
<p>
</p>
<p>As explained above, the number of arithmetic crystal classes is equal to the number of symmorphic space-group types: in dimension 2 there are 13 such classes, in dimension 3 there are 73 arithmetic crystal classes. The Hermann&#8211;Mauguin symbol of the symmorphic space-group type to which a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> belongs is obtained from the symbol for the space-group type of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> by replacing any screw-rotation axis symbol <span class="it"><i>N</i></span><span class="inf"><sub><span class="it"><i>m</i></span></sub></span> by the corresponding rotation axis symbol <span class="it"><i>N</i></span> and every glide-plane symbol <span class="it"><i>a</i></span>, <span class="it"><i>b</i></span>, <span class="it"><i>c</i></span>, <span class="it"><i>d</i></span>, <span class="it"><i>e</i></span>, <span class="it"><i>n</i></span> by the symbol <span class="it"><i>m</i></span> for a mirror plane.</p>
<p>It is clear that the classification into arithmetic crystal classes refines both the classifications into geometric crystal classes and into Bravais classes, since in the first case only the point groups and in the second case only the translation lattices are taken into account, whereas for the arithmetic crystal classes the combination of point groups and translation lattices is considered. Note, however, that for the determination of the arithmetic crystal class of a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> it is not sufficient to look only at the type of the point group and the Bravais type of the translation lattice. It is crucial to consider the action of the point group on the translation lattice.</p>
<enun id="example1o3o4o4o1o3" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o1" secnum="enun1.3.4.4.1">Example</st>
<p>Let <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> be space groups of types <span class="it"><i>P</i></span>3<span class="it"><i>m</i></span>1 (156) and <span class="it"><i>P</i></span>31<span class="it"><i>m</i></span> (157), respectively. Since <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> are symmorphic space groups of different types, they must belong to different arithmetic classes. The point groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/acch1o3/acch1o3fi895.svg" alt="[{\cal G}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> both belong to the same geometric crystal class with symbol 3<span class="it"><i>m</i></span> and the translation lattices of both space groups are primitive hexagonal lattices, and thus of the same Bravais type. It is the different action on the translation lattice which causes <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> to lie in different arithmetic classes:</p>
<p>In the conventional setting, the point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;"/> contains the threefold rotation<span class="fd"><a name="fdu53"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd86.svg" alt="[{\bi R} = \pmatrix{ 0 &amp; -1 &amp; 0 \cr 1 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } ]" class="mathimage" style="max-width: 100%; height: auto; width: 115px;"/></span>and the reflections<span class="fd"><a name="fdu54"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd87.svg" alt="[\displaylines{{\bi M}_1 = \pmatrix{ 0 &amp; -1 &amp; 0 \cr -1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 } ,\quad {\bi M}_2 = \pmatrix{ -1 &amp; 1 &amp; 0 \cr 0 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 }\cr {\rm and}\ {\bi M}_3 = \pmatrix{ 1 &amp; 0 &amp; 0 \cr 1 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } , }]" class="mathimage" style="max-width: 100%; height: auto; width: 286px;"/></span>whereas the point group <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> of <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> contains the same rotation <img src="/teximages/acch1o3/acch1o3fi902.svg" alt="[{\bi R}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;"/> and the reflections<span class="fd"><a name="fdu55"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd88.svg" alt="[\displaylines{ {\bi M}_1' = \pmatrix{ 0 &amp; 1 &amp; 0 \cr 1 &amp; 0 &amp; 0 \cr 0 &amp; 0 &amp; 1 } ,\quad {\bi M}_2' = \pmatrix{ 1 &amp; -1 &amp; 0 \cr 0 &amp; -1 &amp; 0 \cr 0 &amp; 0 &amp; 1 }\cr {\rm and}\ {\bi M}_3' = \pmatrix{ -1 &amp; 0 &amp; 0 \cr -1 &amp; 1 &amp; 0 \cr 0 &amp; 0 &amp; 1 } . }]" class="mathimage" style="max-width: 100%; height: auto; width: 263px;"/></span>Since the threefold rotation is represented by the same matrix in both groups, the lattice basis for both groups can be taken as the conventional basis <img src="/teximages/acch1o2/acch1o2fi42.svg" alt="[{\bf a}, {\bf b}, {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;"/> of a hexagonal lattice, with <span class="b"><b>a</b></span> and <span class="b"><b>b</b></span> of the same length and enclosing an angle of 120&#176; and <span class="b"><b>c</b></span> perpendicular to the plane spanned by <span class="b"><b>a</b></span> and <span class="b"><b>b</b></span>. One now sees that in <img src="/teximages/acch1o3/acch1o3fi674.svg" alt="[{\cal P}' ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;"/> the reflection planes of <img src="/teximages/acch1o3/acch1o3fi905.svg" alt="[{\bi M}_1']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.955516pt;"/>, <img src="/teximages/acch1o3/acch1o3fi906.svg" alt="[{\bi M}_2']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.955516pt;"/> and <img src="/teximages/acch1o3/acch1o3fi907.svg" alt="[{\bi M}_3']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.06668pt;"/> contain the vectors <img src="/teximages/acch1o1/acch1o1fi19.svg" alt="[{\bf a} + {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747999999997pt;"/>, <span class="b"><b>a</b></span> and <span class="b"><b>b</b></span>, respectively, whereas in <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;"/> these vectors are just perpendicular to the reflection planes. In the so-called hexagonally centred lattice with primitive basis <img src="/teximages/acch1o3/acch1o3fi910.svg" alt="[{\bf a}' = \textstyle{{1}\over{3}} {\bf a} + \textstyle{{2}\over{3}} {\bf b} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>, <img src="/teximages/acch1o3/acch1o3fi911.svg" alt="[{\bf b}' = -\textstyle{{2}\over{3}} {\bf a} - \textstyle{{1}\over{3}} {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -4.233781pt;"/>, <img src="/teximages/abch2o2/abch2o2fi375.svg" alt="[{\bf c}' = {\bf c}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/>, the vectors <img src="/teximages/abch4o3/abch4o3fi269.svg" alt="[{\bf a}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> and <img src="/teximages/abch4o3/abch4o3fi270.svg" alt="[{\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166747000000001pt;"/> are perpendicular to the vectors <span class="b"><b>a</b></span> and <span class="b"><b>b</b></span>. The group <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;"/> can thus be regarded as the action of <img src="/teximages/acch1o3/acch1o3fi9.svg" alt="[{\cal G} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> on the hexagonally centred lattice, showing that <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;" loading="lazy"/> are actions of the same group on different lattices which therefore belong to different arithmetic crystal classes.</p>
</enun>
<p>
</p>
<p>As we have seen, the assignment of a space group to its arithmetic crystal class is equivalent to the assignment to its corresponding symmorphic space group, which in turn can be seen as an assignment to the combination of a point group and a lattice on which this point group acts. This correspondence between arithmetic crystal classes and point group/lattice combinations is reflected in the symbol for an arithmetic crystal class suggested in de Wolff <span class="it"><i>et al.</i></span> (1985<bbr id="bb5"/>), which is the symbol of the symmorphic space group with the letter for the lattice moved to the end, <span class="it"><i>e.g.</i></span> 4<span class="it"><i>mmP</i></span> for the arithmetic crystal class containing the symmorphic space groups of type <span class="it"><i>P</i></span>4<span class="it"><i>mm</i></span> (99) and the non-symmorphic groups derived from this symmorphic group, <span class="it"><i>i.e.</i></span> the groups of space-group type <span class="it"><i>P</i></span>4<span class="it"><i>bm</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>cm</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>nm</i></span>, <span class="it"><i>P</i></span>4<span class="it"><i>cc</i></span>, <span class="it"><i>P</i></span>4<span class="it"><i>nc</i></span>, <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>mc</i></span> and <span class="it"><i>P</i></span>4<span class="inf"><sub>2</sub></span><span class="it"><i>bc</i></span> (100&#8211;106).</p>
<p>Recall that the members of one arithmetic crystal class are space groups with the same translation lattice and the same point group, possibly written with respect to different primitive bases. If the point group happens to be the Bravais group of the translation lattice, this is independent of the chosen primitive basis and thus being a Bravais group is clearly a property of the full arithmetic crystal class.</p>
<enun id="definition1o3o4o4o1o4" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o1" secnum="enun1.3.4.4.1">Definition</st>
<p>The arithmetic crystal class of a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> is called a <span class="it"><i>Bravais arithmetic crystal class</i></span><indexg><index type="s" id="acch1o3index00115" significance="standard">Bravais arithmetic crystal class</index></indexg> if the point group of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> is the Bravais group of the translation lattice of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/>.</p>
<p>The arithmetic crystal class of an integral matrix group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> is a Bravais arithmetic crystal class if <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> is maximal among the integral matrix groups with the same space of metric tensors <img src="/teximages/acch1o3/acch1o3fi924.svg" alt="[{\bf M}({\cal P})]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.10816pt;" loading="lazy"/>, <span class="it"><i>i.e.</i></span> if for any integral matrix group <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> properly containing <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> as a subgroup, the space of metric tensors <img src="/teximages/acch1o3/acch1o3fi927.svg" alt="[{\bf M}({\cal P}') ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.108159pt;" loading="lazy"/> is strictly smaller than that of <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/>. This amounts to saying that <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> must act on a lattice with specialized metric.</p>
</enun>
<p>
</p>
<p>Note that in the previous edition of <span class="it"><i>IT</i></span> A the shorter term <span class="it"><i>Bravais class</i></span> was used as a synonym for Bravais arithmetic crystal class. However, in this edition the term <span class="it"><i>Bravais class</i></span> is reserved for the classification of space-group types according to their lattices (see Section 1.3.4.3<secr id="sec1o3o4o3"/>).</p>
<p>Since the lattice types are characterized by their Bravais groups, the Bravais arithmetic crystal classes are in one-to-one correspondence with the Bravais types of lattices. The 14 Bravais arithmetic crystal classes (given by the symbol for the arithmetic class, with the number of the associated symmorphic space-group type in brackets) and the corresponding lattice types are: <img src="/teximages/abch1o3/abch1o3fi85.svg" alt="[\bar{1}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 6px;" loading="lazy"/><span class="it"><i>P</i></span> (2), triclinic; 2/<span class="it"><i>mP</i></span> (10), primitive monoclinic; 2/<span class="it"><i>mC</i></span> (12), centred monoclinic; <span class="it"><i>mmmP</i></span> (47), primitive orthorhombic; <span class="it"><i>mmmC</i></span> (65), single-face-centred orthorhombic; <span class="it"><i>mmmF</i></span> (69), all-face-centred orthorhombic; <span class="it"><i>mmmI</i></span> (71), body-centred ortho&#173;rhombic; 4/<span class="it"><i>mmmP</i></span> (123), primitive tetragonal; 4/<span class="it"><i>mmmI</i></span> (139), body-centred tetragonal; <img src="/teximages/acch1o3/acch1o3fi931.svg" alt="[\bar{3}mR]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> (166), rhombohedral; 6/<span class="it"><i>mmmP</i></span> (191), hexagonal; <img src="/teximages/acch1o3/acch1o3fi932.svg" alt="[m\bar{3}mP]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> (221), primitive cubic; <img src="/teximages/acch1o3/acch1o3fi933.svg" alt="[m\bar{3}mF]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> (225), face-centred cubic; and <img src="/teximages/abch8o2/abch8o2fi145.svg" alt="[m\bar{3}mI]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> (229), body-centred cubic.</p>
<p><span class="it"><i>Bravais flocks</i></span><indexg><index type="s" id="acch1o3index00116" significance="standard">Bravais flock</index></indexg></p>
<p>In the classification of space groups according to their translation lattices, the point groups play only a secondary role (as groups acting on the lattices). From the perspective of arithmetic crystal classes, this classification can now be reformulated in terms of integral matrix groups. The crucial point is that every arithmetic crystal class can be assigned to a Bravais arithmetic crystal class in a natural way: If <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> is a point group, there is a unique Bravais arithmetic crystal class containing a Bravais group <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> of minimal order with <img src="/teximages/acch1o3/acch1o3fi937.svg" alt="[{\cal P} \leq {\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.637859pt;" loading="lazy"/>. Conversely, a Bravais group <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> acting on a lattice <img src="/teximages/acch1o3/acch1o3fi47.svg" alt="[{\bf L}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/> is grouped together with its subgroups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> that do not act on a more general lattice, <span class="it"><i>i.e.</i></span> on a lattice <img src="/teximages/acch1o3/acch1o3fi710.svg" alt="[{\bf L}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;" loading="lazy"/> with more free parameters than <img src="/teximages/acch1o3/acch1o3fi122.svg" alt="[{\bf L} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/>. This observation gives rise to the concept of <span class="it"><i>Bravais flocks</i></span>, which is mainly applied to matrix groups.</p>
<enun id="definition1o3o4o4o1o5" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o1" secnum="enun1.3.4.4.1">Definition</st>
<p>Two integral matrix groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> belong to the same Bravais flock if they are both conjugate by an integral basis transformation to subgroups of a common Bravais group, <span class="it"><i>i.e.</i></span> if there exists a Bravais group <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> and integral 3 &#215; 3 matrices <img src="/teximages/abch5o1/abch5o1fi146.svg" alt="[{\bi P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi947.svg" alt="[{\bi P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.77635683940025e-15pt;" loading="lazy"/> such that <img src="/teximages/acch1o3/acch1o3fi948.svg" alt="[{\bi P} {\bi W} {\bi P}^{-1} \in {\cal B} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478207000000001pt;" loading="lazy"/> for all <img src="/teximages/acch1o3/acch1o3fi537.svg" alt="[{\bi W} \in {\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi950.svg" alt="[{\bi P}' {\bi W}' {\bi P}'^{-1} \in {\cal B} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478207000000001pt;" loading="lazy"/> for all <img src="/teximages/acch1o3/acch1o3fi951.svg" alt="[{\bi W}' \in {\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/>. Moreover, <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> must all have spaces of metric tensors of the same dimension.</p>
<p>Each Bravais flock consists of the union of the arithmetic crystal class of a Bravais group <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> and the arithmetic crystal classes of the subgroups of <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> that do not act on a more general lattice than <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/>.</p>
</enun>
<p>
</p>
<p>The classification of space groups into Bravais flocks is the same as that according to the Bravais types of lattices and as that into Bravais classes. If the point groups <img src="/teximages/acch1o3/acch1o3fi395.svg" alt="[{\cal P} ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> of two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;" loading="lazy"/> belong to the same Bravais flock, then the space groups are also said to belong to the same Bravais flock, but this is the case if and only if <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;" loading="lazy"/> belong to the same Bravais class.</p>
<enun id="example1o3o4o4o1o6" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o1" secnum="enun1.3.4.4.1">Example</st>
<p>For the body-centred tetragonal lattice the Bravais arithmetic crystal class is the arithmetic crystal class 4/<span class="it"><i>mmmI</i></span> and the corresponding symmorphic space-group type is <span class="it"><i>I</i></span>4/<span class="it"><i>mmm</i></span> (139). The other arithmetic crystal classes in this Bravais flock are (with the number of the corresponding symmorphic space group in brackets): 4<span class="it"><i>I</i></span> (79), <img src="/teximages/acch1o3/acch1o3fi964.svg" alt="[\bar{4}I]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 13px;" loading="lazy"/> (82), 4/<span class="it"><i>mI</i></span> (87), 422<span class="it"><i>I</i></span> (97), 4<span class="it"><i>mmI</i></span> (107), <img src="/teximages/acch1o3/acch1o3fi965.svg" alt="[\bar{4}m2I]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999999pt;" loading="lazy"/> (119) and <img src="/teximages/acch1o3/acch1o3fi966.svg" alt="[\bar{4}2mI]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999999pt;" loading="lazy"/> (121).</p>
</enun>
<p>
</p>
</div>

<div id="divsec1o3o4o4o2" class="sec3" secnum="1.3.4.4.2" fpage="39" lpage="39">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o4o2"><tree level="3"/></a>1.3.4.4.2. Lattice systems<indexg><index id="acch1o3index00117" significance="standard" type="s">lattice system</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o4o2.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o4o2" secnum="1.3.4.4.2">Lattice systems<indexg><index id="acch1o3index00117" significance="standard" type="s">lattice system</index></indexg></st>
<p>It is sometimes convenient to group together those Bravais types of lattices for which the Bravais groups belong to the same holohedry.</p>
<enun id="definition1o3o4o4o2o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o2" secnum="enun1.3.4.4.2">Definition</st>
<p>Two lattices belong to the same <span class="it"><i>lattice system</i></span> if their Bravais groups belong to the same geometric crystal class (which is thus a holohedry).</p>
</enun>
<p>
</p>
<p><span class="it"><i>Remark</i></span>: The lattice systems were called <span class="it"><i>Bravais systems</i></span> in earlier editions of this volume.</p>
<enun id="example1o3o4o4o2o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o2" secnum="enun1.3.4.4.2">Example</st>
<p>The primitive cubic, face-centred cubic and body-centred cubic lattices all belong to the same lattice system, because their Bravais groups all belong to the holohedry with symbol <img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>.</p>
<p>On the other hand, the hexagonal and the rhombohedral lattices belong to different lattice systems, because their Bravais groups are not even of the same order and lie in different holohedries (with symbols 6/<span class="it"><i>mmm</i></span> and <img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, respectively).</p>
</enun>
<p>
</p>
<p>From the definition it is obvious that lattice systems classify lattices because they consist of full Bravais types of lattices. On the other hand, the example of the geometric crystal class <img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> shows that lattice systems do not classify point groups, because depending on the chosen basis a point group in this geometric crystal class belongs to either the hexagonal or the rhombohedral lattice system.</p>
<p>However, since the translation lattices of space groups in the same Bravais class belong to the same Bravais type of lattices, the lattice systems can also be regarded as a classification of space groups in which full Bravais classes are grouped together.</p>
<enun id="definition100" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o2" secnum="enun1.3.4.4.2">Definition</st>
<p>Two Bravais classes belong to the same <span class="it"><i>lattice system</i></span> if the corresponding Bravais arithmetic crystal classes belong to the same holohedry.</p>
<p>More precisely, two space groups <img src="/teximages/acch1o3/acch1o3fi832.svg" alt="[\cal G]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;" loading="lazy"/> belong to the same lattice system if the point groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> are contained in Bravais groups <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi975.svg" alt="[{\cal B}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014000000002pt;" loading="lazy"/>, respectively, such that <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi975.svg" alt="[{\cal B}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014000000002pt;" loading="lazy"/> belong to the same holohedry and such that <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi706.svg" alt="[{\cal B}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi975.svg" alt="[{\cal B}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014000000002pt;" loading="lazy"/> all have spaces of metric tensors of the same dimension.</p>
</enun>
<p>
</p>
<p>Every lattice system contains the lattices of precisely one holohedry and a holohedry determines a unique lattice system, containing the lattices of the Bravais arithmetic crystal classes in the holohedry. Therefore, there is a one-to-one correspondence between holohedries and lattice systems. There are four lattice systems in dimension 2 and seven lattice systems in dimension 3. The lattice systems in three-dimensional space are displayed in Table 1.3.4.1<tabler id="table1o3o4o1" loc="float"/>. Along with the name of each lattice system, the Bravais types of lattices contained in it and the corresponding holohedry are given.</p>
<tableplace id="table1o3o4o1"/>
</div>

<div id="divsec1o3o4o4o3" class="sec3" secnum="1.3.4.4.3" fpage="39" lpage="40">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o4o3"><tree level="3"/></a>1.3.4.4.3. Crystal systems<indexg><index significance="standard" id="acch1o3index00118" type="s">crystal system</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o4o3.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o4o3" secnum="1.3.4.4.3">Crystal systems<indexg><index significance="standard" id="acch1o3index00118" type="s">crystal system</index></indexg></st>
<p>The point groups contained in a geometric crystal class can act on different Bravais types of lattices, which is the reason why lattice systems do not classify point groups. But the action on different types of lattices can be exploited for a classification of point groups by joining those geometric crystal classes that act on the same Bravais types of lattices. For example, the holohedry <img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> acts on primitive, face-centred and body-centred cubic lattices. The other geometric crystal classes that act on these three types of lattices are 23, <img src="/teximages/abch2o2/abch2o2fi25.svg" alt="[m\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 432 and <img src="/teximages/abch2o2/abch2o2fi3.svg" alt="[\bar{4}3m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>.</p>
<enun id="definition1o3o4o4o3o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o3" secnum="enun1.3.4.4.3">Definition</st>
<p>Two space groups <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> and <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;" loading="lazy"/> with point groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/>, respectively, belong to the same <span class="it"><i>crystal system</i></span> if the sets of Bravais types of lattices on which <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> act coincide. Since point groups in the same geometric crystal class act on the same types of lattices, crystal systems consist of full geometric crystal classes and the point groups <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> are also said to belong to the same crystal system.</p>
</enun>
<p>
</p>
<p><span class="it"><i>Remark</i></span>: In the literature there are many different notions of crystal systems. In <span class="it"><i>International Tables</i></span>, only the one defined above is used.</p>
<p>In many cases, crystal systems collect together geometric crystal classes for point groups that are in a group&#8211;subgroup relation and act on lattices with the same number of free parameters. However, this condition is not sufficient. If a point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> is a subgroup of another point group <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/>, it is clear that <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> acts on each lattice on which <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> acts. But <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> may in addition act on different types of lattices on which <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> does not act.</p>
<p>Note that it is sufficient to consider the action on lattices with the maximal number of free parameters, since the action on these lattices implies the action on lattices with a smaller number of free parameters (corresponding to metric specializations).</p>
<enun id="example1o3o4o4o3o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o3" secnum="enun1.3.4.4.3">Example</st>
<p>The holohedry of type 4/<span class="it"><i>mmm</i></span> acts on tetragonal and body-centred tetragonal lattices. The crystal system containing this holohedry thus consists of all the geometric crystal classes in which the point groups act on tetragonal and body-centred tetragonal lattices, but not on lattices with more than two free parameters. This is the case for all geometric crystal classes with point groups containing a fourfold rotation or roto&#173;inversion and that are subgroups of a point group of type 4/<span class="it"><i>mmm</i></span>. This means that the crystal system containing the holohedry 4/<span class="it"><i>mmm</i></span> consists of the geometric classes of types 4, <img src="/teximages/abch1o4/abch1o4fi129.svg" alt="[\bar{4}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 7px;" loading="lazy"/>, 4/<span class="it"><i>m</i></span>, 422, 4<span class="it"><i>mm</i></span>, <img src="/teximages/abch2o2/abch2o2fi99.svg" alt="[\bar{4}2m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999999pt;" loading="lazy"/> and 4/<span class="it"><i>mmm</i></span>.</p>
</enun>
<p>
</p>
<p>This example is typical for the situation in three-dimensional space, since in three-dimensional space usually all the arithmetic crystal classes contained in a holohedry are Bravais arithmetic crystal classes. In this case, the geometric crystal classes in the crystal system of the holohedry are simply the classes of those subgroups of a point group in the holohedry that do not act on lattices with a larger number of free parameters.</p>
<p>The only exceptions from this situation are the Bravais arithmetic crystal classes for the hexagonal and rhombohedral lattices.</p>
<enun id="example1o3o4o4o3o3" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o3" secnum="enun1.3.4.4.3">Example</st>
<p>A point group containing a threefold rotation but no sixfold rotation or rotoinversion acts both on a hexagonal lattice and on a rhombohedral lattice. On the other hand, point groups containing a sixfold rotation only act on a hexagonal but not on a rhombohedral lattice. The geometric crystal classes of point groups containing a threefold rotation or rotoinversion but not a sixfold rotation or rotoinversion form a crystal system which is called the <span class="it"><i>trigonal crystal system</i></span>. The geometric crystal classes of point groups containing a sixfold rotation or rotoinversion form a different crystal system, which is called the <span class="it"><i>hexagonal crystal system</i></span>.</p>
</enun>
<p>
</p>
<p>The classification of the point-group types into crystal systems is summarized in Table 1.3.4.2<tabler id="table1o3o4o2" loc="float"/>.</p>
<tableplace id="table1o3o4o2"/>
<p><span class="it"><i>Remark</i></span>: Crystal systems can contain at most one holohedry and in dimensions 2 and 3 it is true that every crystal system does contain a holohedry. However, this is not true in higher dimensions. The smallest counter-examples exist in dimension 5, where two (out of 59) crystal systems do not contain any holohedry.</p>
</div>

<div id="divsec1o3o4o4o4" class="sec3" secnum="1.3.4.4.4" fpage="40" lpage="41">
<div class="sectionheaders">
<h4 class="sectionheaders"><a name="sec1o3o4o4o4"><tree level="3"/></a>1.3.4.4.4. Crystal families<indexg><index type="s" id="acch1o3index00119" significance="standard">crystal family</index></indexg></h4>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/sec1o3o4o4o4.pdf">pdf</a> |</span>
</div>
<st secid="sec1o3o4o4o4" secnum="1.3.4.4.4">Crystal families<indexg><index type="s" id="acch1o3index00119" significance="standard">crystal family</index></indexg></st>
<p>The classification into crystal systems has many important applications, but it has the disadvantage that it is not compatible with the classification into lattice systems. Space groups that belong to the hexagonal lattice system are distributed over the trigonal and the hexagonal crystal system. Conversely, space groups in the trigonal crystal system belong to either the rhombohedral or the hexagonal lattice system. It is therefore desirable to define a further classification level in which the classes consist of full crystal systems and of full lattice systems, or, equivalently, of full geometric crystal classes and full Bravais classes. Since crystal systems already contain only geometric crystal classes with spaces of metric tensors of the same dimension, this can be achieved by the following definition.</p>
<enun id="definition1o3o4o4o4o1" type="LONG">

<h4 class="enunlong"><i>Definition</i></h4>
<st enunid="enunsec1o3o4o4o4" secnum="enun1.3.4.4.4">Definition</st>
<p>For a space group <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> with point group <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> the <span class="it"><i>crystal family</i></span> of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> is the union of all geometric crystal classes that contain a space group <img src="/teximages/abch8o2/abch8o2fi5.svg" alt="[{\cal G}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422665pt;" loading="lazy"/> that has the same Bravais type of lattices as <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/>.</p>
<p>The crystal family of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> thus consists of those geometric crystal classes that contain a point group <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> such that <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> are contained in a common supergroup <img src="/teximages/acch1o3/acch1o3fi1010.svg" alt="[\cal B]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> (which is a Bravais group) and such that <img src="/teximages/abch1o1/abch1o1fi106.svg" alt="[{\cal P}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597758999999998pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi672.svg" alt="[{\cal P}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.597759000000002pt;" loading="lazy"/> and <img src="/teximages/acch1o3/acch1o3fi1010.svg" alt="[\cal B]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.263014pt;" loading="lazy"/> all act on lattices with the same number of free parameters.</p>
</enun>
<p>
</p>
<p>In two-dimensional space, the crystal families coincide with the crystal systems and in three-dimensional space only the trigonal and hexagonal crystal system are merged into a single crystal family, whereas all other crystal systems again form a crystal family on their own.</p>
<enun id="example1o3o4o4o4o2" type="LONG">

<h4 class="enunlong"><i>Example</i></h4>
<st enunid="enunsec1o3o4o4o4" secnum="enun1.3.4.4.4">Example</st>
<p>The trigonal and hexagonal crystal systems belong to a single crystal family, called the <span class="it"><i>hexagonal crystal family</i></span>, because for both crystal systems the number of free parameters of the corresponding lattices is 2 and a point group of type <img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> in the trigonal crystal system is a subgroup of a point group of type 6/<span class="it"><i>mmm</i></span> in the hexagonal crystal system.</p>
</enun>
<p>
</p>
<p>A space group in the hexagonal crystal family belongs to either the trigonal or the hexagonal crystal system and to either the rhombohedral or the hexagonal lattice system. A group in the hexagonal crystal system cannot belong to the rhombohedral lattice system, but all other combinations of crystal system and lattice system are possible. The distribution of the space groups in the hexagonal crystal family over these different combinations is displayed in Table 1.3.4.3<tabler id="table1o3o4o3" loc="float"/>.</p>
<tableplace id="table1o3o4o3"/>
<p><span class="it"><i>Remark</i></span>: Up to dimension 3 it seems exceptional that a crystal family contains more than one crystal system, since the only instance of this phenomenon is the hexagonal crystal family consisting of the trigonal and the hexagonal crystal systems. However, in higher dimensions it actually becomes rare that a crystal family consists only of a single crystal system.</p>
<p>For the space groups within one crystal family the same coordinate system is usually used, which is called the <span class="it"><i>conventional coordinate system</i></span><indexg><index type="s" id="acch1o3index00120" significance="standard">conventional coordinate system</index><index significance="standard" id="acch1o3index00121" type="s">coordinate system<index significance="standard" id="acch1o3index00122" type="s">conventional</index></index></indexg> (for this crystal family). However, depending on the application it may be useful to work with a different coordinate system. To avoid confusion, it is recommended to state explicitly when a coordinate system differing from the conventional coordinate system is used.<figwrap id="fig1o3o2o1" fpage="23" lpage="23">
<div class="fig">
<table summary="Figure 1.3.2.1" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;" width="98%" cellpadding="2" border="0" bgcolor="#ddeedd"><tbody>
<tr>
<td align="center" width="20%" style="border:solid 1px #ddeedd;">
<a class="linkclass" href="/Ac/ch1o3v0001/fig1o3o2o1/"><img src="/figures/Acfig1o3o2o1thm.gif" align="middle" alt="[Figure 1.3.2.1]" style="box-shadow: 3px 3px 10px #aaa;"/>
<br/></a>
</td>
<td style="border:solid 1px #ddeedd;">
<p><span class="size3"><b><a name="fig1o3o2o1">Figure 1.3.2.1</a></b></span>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/fig1o3o2o1.pdf">pdf</a> |</span></p><p>Conventional basis <img src="/teximages/abch15o2/abch15o2fi1476.svg" alt="[{\bf a}, {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> and a non-conventional basis <img src="/teximages/acch1o3/acch1o3fi58.svg" alt="[{\bf a}', {\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> for the square lattice.</p>
</td>
</tr>
</tbody>
</table>
</div>
<caption><p>Conventional basis <img src="/teximages/abch15o2/abch15o2fi1476.svg" alt="[{\bf a}, {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> and a non-conventional basis <img src="/teximages/acch1o3/acch1o3fi58.svg" alt="[{\bf a}', {\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> for the square lattice.</p></caption>
<short-figcaption><p>Conventional basis <img src="/teximages/abch15o2/abch15o2fi1476.svg" alt="[{\bf a}, {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> and a non-conventional basis <img src="/teximages/acch1o3/acch1o3fi58.svg" alt="[{\bf a}', {\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> for the square lattice</p></short-figcaption>
</figwrap>
<figwrap id="fig1o3o2o2" fpage="24" lpage="24">
<div class="fig">
<table summary="Figure 1.3.2.2" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;" width="98%" cellpadding="2" border="0" bgcolor="#ddeedd"><tbody>
<tr>
<td align="center" width="20%" style="border:solid 1px #ddeedd;">
<a class="linkclass" href="/Ac/ch1o3v0001/fig1o3o2o2/"><img src="/figures/Acfig1o3o2o2thm.gif" align="middle" alt="[Figure 1.3.2.2]" style="box-shadow: 3px 3px 10px #aaa;"/>
<br/></a>
</td>
<td style="border:solid 1px #ddeedd;">
<p><span class="size3"><b><a name="fig1o3o2o2">Figure 1.3.2.2</a></b></span>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/fig1o3o2o2.pdf">pdf</a> |</span></p><p>Vorono&#239; domains and primitive unit cells for a rectangular lattice (<span class="it"><i>a</i></span>) and an oblique lattice (<span class="it"><i>b</i></span>).</p>
</td>
</tr>
</tbody>
</table>
</div>
<caption><p>Vorono&#239; domains and primitive unit cells for a rectangular lattice (<span class="it"><i>a</i></span>) and an oblique lattice (<span class="it"><i>b</i></span>).</p></caption>
<short-figcaption><p>Vorono&#239; domains and primitive unit cells for a rectangular lattice (<span class="it"><i>a</i></span>) and an oblique lattice (<span class="it"><i>b</i></span>)</p></short-figcaption>
</figwrap>
<figwrap id="fig1o3o2o3" fpage="25" lpage="25">
<div class="fig">
<table summary="Figure 1.3.2.3" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;" width="98%" cellpadding="2" border="0" bgcolor="#ddeedd"><tbody>
<tr>
<td align="center" width="20%" style="border:solid 1px #ddeedd;">
<a class="linkclass" href="/Ac/ch1o3v0001/fig1o3o2o3/"><img src="/figures/Acfig1o3o2o3thm.gif" align="middle" alt="[Figure 1.3.2.3]" style="box-shadow: 3px 3px 10px #aaa;"/>
<br/></a>
</td>
<td style="border:solid 1px #ddeedd;">
<p><span class="size3"><b><a name="fig1o3o2o3">Figure 1.3.2.3</a></b></span>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/fig1o3o2o3.pdf">pdf</a> |</span></p><p>Primitive rectangular lattice (only the filled nodes) and centred rectangular lattice (filled and open nodes).</p>
</td>
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</tbody>
</table>
</div>
<caption><p>Primitive rectangular lattice (only the filled nodes) and centred rectangular lattice (filled and open nodes).</p></caption>
<short-figcaption><p>Primitive rectangular lattice (only the filled nodes) and centred rectangular lattice (filled and open nodes)</p></short-figcaption>
</figwrap>
<figwrap id="fig1o3o2o4" fpage="25" lpage="25">
<div class="fig">
<table summary="Figure 1.3.2.4" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;" width="98%" cellpadding="2" border="0" bgcolor="#ddeedd"><tbody>
<tr>
<td align="center" width="20%" style="border:solid 1px #ddeedd;">
<a class="linkclass" href="/Ac/ch1o3v0001/fig1o3o2o4/"><img src="/figures/Acfig1o3o2o4thm.gif" align="middle" alt="[Figure 1.3.2.4]" style="box-shadow: 3px 3px 10px #aaa;"/>
<br/></a>
</td>
<td style="border:solid 1px #ddeedd;">
<p><span class="size3"><b><a name="fig1o3o2o4">Figure 1.3.2.4</a></b></span>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/fig1o3o2o4.pdf">pdf</a> |</span></p><p>Primitive cell (dashed line) and centred cell (solid lines) for the centred rectangular lattice.</p>
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</tbody>
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</div>
<caption><p>Primitive cell (dashed line) and centred cell (solid lines) for the centred rectangular lattice.</p></caption>
<short-figcaption><p>Primitive cell (dashed line) and centred cell (solid lines) for the centred rectangular lattice</p></short-figcaption>
</figwrap>
<figwrap id="fig1o3o4o1" fpage="32" lpage="32">
<div class="fig">
<table summary="Figure 1.3.4.1" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;" width="98%" cellpadding="2" border="0" bgcolor="#ddeedd"><tbody>
<tr>
<td align="center" width="20%" style="border:solid 1px #ddeedd;">
<a class="linkclass" href="/Ac/ch1o3v0001/fig1o3o4o1/"><img src="/figures/Acfig1o3o4o1thm.gif" align="middle" alt="[Figure 1.3.4.1]" style="box-shadow: 3px 3px 10px #aaa;"/>
<br/></a>
</td>
<td style="border:solid 1px #ddeedd;">
<p><span class="size3"><b><a name="fig1o3o4o1">Figure 1.3.4.1</a></b></span>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/fig1o3o4o1.pdf">pdf</a> |</span></p><p>Classification levels for three-dimensional space groups.</p>
</td>
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</tbody>
</table>
</div>
<caption><p>Classification levels for three-dimensional space groups.</p></caption>
<short-figcaption><p>Classification levels for three-dimensional space groups</p></short-figcaption>
</figwrap>
<figwrap id="fig1o3o4o2" fpage="33" lpage="33">
<div class="fig">
<table summary="Figure 1.3.4.2" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;" width="98%" cellpadding="2" border="0" bgcolor="#ddeedd"><tbody>
<tr>
<td align="center" width="20%" style="border:solid 1px #ddeedd;">
<a class="linkclass" href="/Ac/ch1o3v0001/fig1o3o4o2/"><img src="/figures/Acfig1o3o4o2thm.gif" align="middle" alt="[Figure 1.3.4.2]" style="box-shadow: 3px 3px 10px #aaa;"/>
<br/></a>
</td>
<td style="border:solid 1px #ddeedd;">
<p><span class="size3"><b><a name="fig1o3o4o2">Figure 1.3.4.2</a></b></span>
<span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/fig1o3o4o2.pdf">pdf</a> |</span></p><p>Space-group diagram of <img src="/teximages/acch1o3/acch1o3fi592.svg" alt="[I4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/> (left) and its reflection in the plane <span class="it"><i>z</i></span> = 0 (right).</p>
</td>
</tr>
</tbody>
</table>
</div>
<caption><p>Space-group diagram of <img src="/teximages/acch1o3/acch1o3fi592.svg" alt="[I4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/> (left) and its reflection in the plane <span class="it"><i>z</i></span> = 0 (right).</p></caption>
<short-figcaption><p>Space-group diagram of <img src="/teximages/acch1o3/acch1o3fi592.svg" alt="[I4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/> (left) and its reflection in the plane <span class="it"><i>z</i></span> = 0 (right)</p></short-figcaption>
</figwrap>

<tablewrap id="table1o3o3o1" tablenum="1.3.3.1" fpage="29" lpage="29">
<div class="table">
<table summary="Automorphism groups of two-dimensional primitive lattices" bgcolor="#ddeedd" border="0" cellpadding="2" width="98%" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;">
<tbody>
<tr>
<td>
<table summary="Automorphism groups of two-dimensional primitive lattices" bgcolor="#ddeedd" class="tbheader" width="100%">
<tbody>
<tr>
<td align="left" bgcolor="#ddeedd" valign="bottom">
<p><span class="size3"><b><a name="table1o3o3o1">Table 1.3.3.1</a></b></span><span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/table1o3o3o1.pdf">pdf</a> | </span><br/>
<span class="size2">Automorphism groups of two-dimensional primitive lattices<indexg><index type="s" id="acch1o3index00123" significance="standard">automorphism group</index></indexg></span>
</p></td>
</tr>
</tbody>
</table>
<table summary="Automorphism groups of two-dimensional primitive lattices" bgcolor="#ddeedd" class="tbheader" width="100%">
<tbody>
<tr>
<td align="left" bgcolor="#ddeedd" valign="bottom">
<p/></td>
</tr>
</tbody>
</table>
<table summary="Automorphism groups of two-dimensional primitive lattices" width="98%" style="margin-left: auto; margin-right: auto; border:1px solid #55aa55; border-radius: 5px;">
<thead valign="top">
<tr>
<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="bottom"><span class="size2">Lattice</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="bottom"><span class="size2">Metric tensor</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="2" align="left" valign="bottom"><span class="size2">Bravais group</span></th></tr>
<tr>
<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Hermann&#8211;Mauguin symbol</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Generators</span></th></tr>
</thead>
<tbody valign="top">
<tr>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Oblique</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="fd"><a name="fdu400"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd89.svg" alt="[\pmatrix{g_{11} &amp; g_{12}\cr &amp; g_{22}} ]" class="mathimage" style="max-width: 100%; height: auto; width: 70px;" loading="lazy"/></span></span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2: <img src="/teximages/acch1o3/acch1o3fi1018.svg" alt="[\bar x, \bar y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Rectangular</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="top"><span class="size2"><span class="fd"><a name="fdu401"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd90.svg" alt="[\pmatrix{g_{11} &amp; 0 \cr &amp; g_{22} } ]" class="mathimage" style="max-width: 100%; height: auto; width: 70px;" loading="lazy"/></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2<span class="it"><i>mm</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2: <img src="/teximages/acch1o3/acch1o3fi1018.svg" alt="[\bar x, \bar y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>m</i></span><span class="inf"><sub>10</sub></span>: <img src="/teximages/acch1o3/acch1o3fi1020.svg" alt="[\bar x, y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
</tr>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Square</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="top"><span class="size2"><span class="fd"><a name="fdu402"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd91.svg" alt="[\pmatrix{g_{11} &amp; 0 \cr &amp; g_{11} } ]" class="mathimage" style="max-width: 100%; height: auto; width: 70px;" loading="lazy"/></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">4<span class="it"><i>mm</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">4<span class="sup"><sup>+</sup></span>: <img src="/teximages/acch1o3/acch1o3fi1021.svg" alt="[\bar y, x]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>m</i></span><span class="inf"><sub>10</sub></span>: <img src="/teximages/acch1o3/acch1o3fi1020.svg" alt="[\bar x, y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Hexagonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="2" colspan="1" align="left" valign="top"><span class="size2"><span class="fd"><a name="fdu403"/><img textype="fd" src="/teximages/acch1o3/acch1o3fd92.svg" alt="[\pmatrix{g_{11} &amp; -{{1}\over{2}} g_{11} \cr &amp; g_{11} } ]" class="mathimage" style="max-width: 100%; height: auto; width: 90px;" loading="lazy"/></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6<span class="it"><i>mm</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6<span class="sup"><sup>+</sup></span>: <img src="/teximages/acch1o3/acch1o3fi1023.svg" alt="[x - y, x]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>m</i></span><span class="inf"><sub>21</sub></span>: <img src="/teximages/acch1o3/acch1o3fi1024.svg" alt="[\bar x, \bar x + y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<caption><span class="size2">Automorphism groups of two-dimensional primitive lattices<indexg><index type="s" id="acch1o3index00123" significance="standard">automorphism group</index></indexg></span></caption>
<short-tbcaption><span class="size2">Automorphism groups of two-dimensional primitive lattices<indexg><index type="s" id="acch1o3index00123" significance="standard">automorphism group</index></indexg></span></short-tbcaption>
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<tablewrap id="table1o3o3o2" tablenum="1.3.3.2" fpage="30" lpage="30">
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<p><span class="size3"><b><a name="table1o3o3o2">Table 1.3.3.2</a></b></span><span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/table1o3o3o2.pdf">pdf</a> | </span><br/>
<span class="size2">Automorphism groups of three-dimensional primitive lattices<indexg><index id="acch1o3index00124" significance="standard" type="s">automorphism group</index></indexg></span>
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<table summary="Automorphism groups of three-dimensional primitive lattices" bgcolor="#ddeedd" class="tbheader" width="100%">
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<table summary="Automorphism groups of three-dimensional primitive lattices" width="98%" style="margin-left: auto; margin-right: auto; border:1px solid #55aa55; border-radius: 5px;">
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<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="bottom"><span class="size2">Lattice</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="bottom"><span class="size2">Metric tensor </span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="2" align="left" valign="bottom"><span class="size2">Bravais group</span></th></tr>
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<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Hermann&#8211;Mauguin symbol</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Generators</span></th></tr>
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<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Triclinic</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1025.svg" alt="[\pmatrix{ g_{11} &amp; g_{12} &amp; g_{13} \cr &amp; g_{22} &amp; g_{23} \cr &amp; &amp; g_{33} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch1o3/abch1o3fi85.svg" alt="[\bar{1}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 6px;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1027.svg" alt="[\bar{1}{:}\ \bar x,\bar y,\bar z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Monoclinic </span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1028.svg" alt="[\pmatrix{ g_{11} &amp; 0 &amp; g_{13} \cr &amp; g_{22} &amp; 0 \cr &amp; &amp; g_{33} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2/<span class="it"><i>m</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1029.svg" alt="[2_{010}{:}\ \bar x,y,\bar z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
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<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1030.svg" alt="[m_{010}{:}\ x,\bar y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Orthorhombic </span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="3" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1031.svg" alt="[\pmatrix{ g_{11} &amp; 0 &amp; 0 \cr &amp; g_{22} &amp; 0 \cr &amp; &amp; g_{33} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>mmm</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1032.svg" alt="[m_{100}{:} \ \bar x,y,z ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1030.svg" alt="[m_{010}{:}\ x,\bar y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1034.svg" alt="[m_{001}{:} \ x,y,\bar z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Tetragonal </span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="3" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1035.svg" alt="[\pmatrix{ g_{11} &amp; 0 &amp; 0 \cr &amp; g_{11} &amp; 0 \cr &amp; &amp; g_{33} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">4/<span class="it"><i>mmm</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1036.svg" alt="[4_{001}{:}\ \bar y,x,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1034.svg" alt="[m_{001}{:} \ x,y,\bar z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1038.svg" alt="[m_{100}{:} \ \bar x,y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Hexagonal </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="3" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1039.svg" alt="[\pmatrix{ g_{11} &amp; -{{1}\over{2}} g_{11} &amp; 0 \cr &amp; g_{11} &amp; 0 \cr &amp; &amp; g_{33} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6/<span class="it"><i>mmm</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1040.svg" alt="[6_{001}{:}\ x-y,x,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1041.svg" alt="[m_{001}{:}\ x,y,\bar z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1042.svg" alt="[m_{100}{:}\ \bar x+y,y,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Rhombohedral </span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1043.svg" alt="[\pmatrix{ g_{11} &amp; g_{12} &amp; g_{12} \cr &amp; g_{11} &amp; g_{12} \cr &amp; &amp; g_{11} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1045.svg" alt="[\bar{3}_{111}{:}\ \bar z,\bar x,\bar y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
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<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1046.svg" alt="[m_{1\bar{1}0}{:}\ y,x,z ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.497343pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Cubic </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="3" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1047.svg" alt="[\pmatrix{ g_{11} &amp; 0 &amp; 0 \cr &amp; g_{11} &amp; 0 \cr &amp; &amp; g_{11} } ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -16.365399pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1034.svg" alt="[m_{001}{:} \ x,y,\bar z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/> </span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1045.svg" alt="[\bar{3}_{111}{:}\ \bar z,\bar x,\bar y]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1051.svg" alt="[m_{110}{:} \ \bar y,\bar x,z]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.453564pt;" loading="lazy"/></span></td>
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<caption><span class="size2">Automorphism groups of three-dimensional primitive lattices<indexg><index id="acch1o3index00124" significance="standard" type="s">automorphism group</index></indexg></span></caption>
<short-tbcaption><span class="size2">Automorphism groups of three-dimensional primitive lattices<indexg><index id="acch1o3index00124" significance="standard" type="s">automorphism group</index></indexg></span></short-tbcaption>
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<tablewrap id="table1o3o3o3" tablenum="1.3.3.3" fpage="30" lpage="30">
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<p><span class="size3"><b><a name="table1o3o3o3">Table 1.3.3.3</a></b></span><span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/table1o3o3o3.pdf">pdf</a> | </span><br/>
<span class="size2">Right-coset decomposition of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;" loading="lazy"/><indexg><index type="s" significance="standard" id="acch1o3index00125">coset decomposition</index></indexg></span>
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</tr>
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</table>
<table summary="Right-coset decomposition of [{\cal G}] relative to [{\cal T}]" bgcolor="#ddeedd" class="tbheader" width="100%">
<tbody>
<tr>
<td align="left" bgcolor="#ddeedd" valign="bottom">
<p/></td>
</tr>
</tbody>
</table>
<table summary="Right-coset decomposition of [{\cal G}] relative to [{\cal T}]" width="98%" style="margin-left: auto; margin-right: auto; border:1px solid #55aa55; border-radius: 5px;">
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<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1054.svg" alt="[\ispecialfonts{\sfi W}_1 = {\sfi e}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1055.svg" alt="[\ispecialfonts{\sfi W}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1056.svg" alt="[ \ispecialfonts{\sfi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2"><img src="/teximages/abch8o2/abch8o2fi210.svg" alt="[\ldots]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/></span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1058.svg" alt="[\ispecialfonts{\sfi W}_{[i]}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.031956pt;" loading="lazy"/></span></th></tr>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1059.svg" alt="[\ispecialfonts{\sfi t}_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1060.svg" alt="[\ispecialfonts{\sfi t}_1 {\sfi W}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1061.svg" alt="[\ispecialfonts{\sfi t}_1 {\sfi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1062.svg" alt="[\ldots ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1063.svg" alt="[\ispecialfonts{\sfi t}_1 {\sfi W}_{[i]}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.031956pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1064.svg" alt="[\ispecialfonts{\sfi t}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1065.svg" alt="[\ispecialfonts{\sfi t}_2 {\sfi W}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1066.svg" alt="[\ispecialfonts{\sfi t}_2 {\sfi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1062.svg" alt="[\ldots ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1068.svg" alt="[\ispecialfonts{\sfi t}_2 {\sfi W}_{[i]}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.031956pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1069.svg" alt="[\ispecialfonts{\sfi t}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1070.svg" alt="[\ispecialfonts{\sfi t}_3 {\sfi W}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1071.svg" alt="[\ispecialfonts{\sfi t}_3 {\sfi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1062.svg" alt="[\ldots ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1073.svg" alt="[\ispecialfonts{\sfi t}_3 {\sfi W}_{[i]}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.031956pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1074.svg" alt="[\ispecialfonts{\sfi t}_4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1075.svg" alt="[\ispecialfonts{\sfi t}_4 {\sfi W}_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1076.svg" alt="[\ispecialfonts{\sfi t}_4 {\sfi W}_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.848846pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1062.svg" alt="[\ldots ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -9.99999995698886e-07pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1078.svg" alt="[\ispecialfonts{\sfi t}_4 {\sfi W}_{[i]}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -3.031956pt;" loading="lazy"/></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1079.svg" alt="[\vdots]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -8.101127pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1079.svg" alt="[\vdots]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -8.101127pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1079.svg" alt="[\vdots]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -8.101127pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" valign="top"><span class="size2"><img src="/teximages/acch1o3/acch1o3fi1079.svg" alt="[\vdots]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -8.101127pt;" loading="lazy"/></span></td>
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</div>
<caption><span class="size2">Right-coset decomposition of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;" loading="lazy"/><indexg><index type="s" significance="standard" id="acch1o3index00125">coset decomposition</index></indexg></span></caption>
<short-tbcaption><span class="size2">Right-coset decomposition of <img src="/teximages/abpre4/abpre4fi6.svg" alt="[{\cal G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.422666pt;" loading="lazy"/> relative to <img src="/teximages/abch1o1/abch1o1fi97.svg" alt="[{\cal T}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.812952000000001pt;" loading="lazy"/><indexg><index type="s" significance="standard" id="acch1o3index00125">coset decomposition</index></indexg></span></short-tbcaption>
</tablewrap>

<tablewrap id="table1o3o4o1" tablenum="1.3.4.1" fpage="39" lpage="39">
<div class="table">
<table summary="Lattice systems in three-dimensional space" bgcolor="#ddeedd" border="0" cellpadding="2" width="98%" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;">
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<td>
<table summary="Lattice systems in three-dimensional space" bgcolor="#ddeedd" class="tbheader" width="100%">
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<td align="left" bgcolor="#ddeedd" valign="bottom">
<p><span class="size3"><b><a name="table1o3o4o1">Table 1.3.4.1</a></b></span><span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/table1o3o4o1.pdf">pdf</a> | </span><br/>
<span class="size2">Lattice systems in three-dimensional space<indexg><index significance="standard" id="acch1o3index00126" type="s">lattice system</index><index significance="standard" id="acch1o3index00127" type="s">Bravais type of lattice</index><index id="acch1o3index00128" significance="standard" type="s">holohedry</index></indexg></span>
</p></td>
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</table>
<table summary="Lattice systems in three-dimensional space" bgcolor="#ddeedd" class="tbheader" width="100%">
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<td align="left" bgcolor="#ddeedd" valign="bottom">
<p/></td>
</tr>
</tbody>
</table>
<table summary="Lattice systems in three-dimensional space" width="98%" style="margin-left: auto; margin-right: auto; border:1px solid #55aa55; border-radius: 5px;">
<thead valign="top">
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<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Lattice system</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Bravais types of lattices</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Holohedry</span></th></tr>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Triclinic (anorthic)</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>aP</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch1o3/abch1o3fi85.svg" alt="[\bar{1}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 6px;" loading="lazy"/></span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Monoclinic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>mP</i></span>, <span class="it"><i>mS</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2/<span class="it"><i>m</i></span></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Orthorhombic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>oP</i></span>, <span class="it"><i>oS</i></span>, <span class="it"><i>oF</i></span>, <span class="it"><i>oI</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>mmm</i></span></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Tetragonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>tP</i></span>, <span class="it"><i>tI</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">4/<span class="it"><i>mmm</i></span></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Hexagonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>hP</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6/<span class="it"><i>mmm</i></span></span></td>
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<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Rhombohedral</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>hR</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/></span></td>
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<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Cubic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>cP</i></span>, <span class="it"><i>cF</i></span>, <span class="it"><i>cI</i></span></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/></span></td>
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</tbody>
</table>
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</table>
</div>
<caption><span class="size2">Lattice systems in three-dimensional space<indexg><index significance="standard" id="acch1o3index00126" type="s">lattice system</index><index significance="standard" id="acch1o3index00127" type="s">Bravais type of lattice</index><index id="acch1o3index00128" significance="standard" type="s">holohedry</index></indexg></span></caption>
<short-tbcaption><span class="size2">Lattice systems in three-dimensional space<indexg><index significance="standard" id="acch1o3index00126" type="s">lattice system</index><index significance="standard" id="acch1o3index00127" type="s">Bravais type of lattice</index><index id="acch1o3index00128" significance="standard" type="s">holohedry</index></indexg></span></short-tbcaption>
</tablewrap>

<tablewrap id="table1o3o4o2" tablenum="1.3.4.2" fpage="39" lpage="39">
<div class="table">
<table summary="Crystal systems in three-dimensional space" bgcolor="#ddeedd" border="0" cellpadding="2" width="98%" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;">
<tbody>
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<table summary="Crystal systems in three-dimensional space" bgcolor="#ddeedd" class="tbheader" width="100%">
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<p><span class="size3"><b><a name="table1o3o4o2">Table 1.3.4.2</a></b></span><span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/table1o3o4o2.pdf">pdf</a> | </span><br/>
<span class="size2">Crystal systems in three-dimensional space<indexg><index type="s" id="acch1o3index00129" significance="standard">crystal system</index><index type="s" id="acch1o3index00130" significance="standard">point-group types</index></indexg></span>
</p></td>
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</table>
<table summary="Crystal systems in three-dimensional space" bgcolor="#ddeedd" class="tbheader" width="100%">
<tbody>
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<td align="left" bgcolor="#ddeedd" valign="bottom">
<p/></td>
</tr>
</tbody>
</table>
<table summary="Crystal systems in three-dimensional space" width="98%" style="margin-left: auto; margin-right: auto; border:1px solid #55aa55; border-radius: 5px;">
<thead valign="top">
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<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Crystal system</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Point-group types </span></th></tr>
</thead>
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<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Triclinic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch1o3/abch1o3fi85.svg" alt="[\bar{1}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 6px;" loading="lazy"/>, 1</span></td>
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<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Monoclinic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">2/<span class="it"><i>m</i></span>, <span class="it"><i>m</i></span>, 2</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Orthorhombic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>mmm</i></span>, <span class="it"><i>mm</i></span>2, 222</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Tetragonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">4/<span class="it"><i>mmm</i></span>, <img src="/teximages/abch2o2/abch2o2fi99.svg" alt="[\bar{4}2m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.107194999999999pt;" loading="lazy"/>, 4<span class="it"><i>mm</i></span>, 422, 4/<span class="it"><i>m</i></span>, <img src="/teximages/abch1o4/abch1o4fi129.svg" alt="[\bar{4}]" class="img_align_bottom" style="max-width: 100%; height: auto; width: 7px;" loading="lazy"/>, 4</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Hexagonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6/<span class="it"><i>mmm</i></span>, <img src="/teximages/abch2o2/abch2o2fi100.svg" alt="[\bar{6}2m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 6<span class="it"><i>mm</i></span>, 622, 6/<span class="it"><i>m</i></span>, <img src="/teximages/abch1o4/abch1o4fi130.svg" alt="[\bar{6}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 6</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Trigonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 3<span class="it"><i>m</i></span>, 32, <img src="/teximages/abch1o4/abch1o4fi128.svg" alt="[\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 3</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Cubic</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o2/abch2o2fi26.svg" alt="[m\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch2o2/abch2o2fi3.svg" alt="[\bar{4}3m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 432, <img src="/teximages/abch2o2/abch2o2fi25.svg" alt="[m\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, 23</span></td>
</tr>
</tbody>
</table>
</td>
</tr>
</tbody>
</table>
</div>
<caption><span class="size2">Crystal systems in three-dimensional space<indexg><index type="s" id="acch1o3index00129" significance="standard">crystal system</index><index type="s" id="acch1o3index00130" significance="standard">point-group types</index></indexg></span></caption>
<short-tbcaption><span class="size2">Crystal systems in three-dimensional space<indexg><index type="s" id="acch1o3index00129" significance="standard">crystal system</index><index type="s" id="acch1o3index00130" significance="standard">point-group types</index></indexg></span></short-tbcaption>
</tablewrap>

<tablewrap id="table1o3o4o3" tablenum="1.3.4.3" fpage="40" lpage="40">
<div class="table">
<table summary="Distribution of space-group types in the hexagonal crystal family" bgcolor="#ddeedd" border="0" cellpadding="2" width="98%" style="margin-left: auto; margin-right: auto; border: 1px solid #55aa55; border-radius: 5px;">
<tbody>
<tr>
<td>
<table summary="Distribution of space-group types in the hexagonal crystal family" bgcolor="#ddeedd" class="tbheader" width="100%">
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<td align="left" bgcolor="#ddeedd" valign="bottom">
<p><span class="size3"><b><a name="table1o3o4o3">Table 1.3.4.3</a></b></span><span class="navlinks"><span class="topnavlinks">| <a class="navlinks" href="#top">top</a></span> | <a class="navlinks" href="/Ac/ch1o3v0001/table1o3o4o3.pdf">pdf</a> | </span><br/>
<span class="size2">Distribution of space-group types in the hexagonal crystal family<indexg><index type="s" significance="standard" id="acch1o3index00131">hexagonal crystal family<index type="s" significance="standard" id="acch1o3index00132">distribution of space-group types in</index></index></indexg></span>
</p></td>
</tr>
</tbody>
</table>
<table summary="Distribution of space-group types in the hexagonal crystal family" bgcolor="#ddeedd" class="tbheader" width="100%">
<tbody>
<tr>
<td align="left" bgcolor="#ddeedd" valign="bottom">
<p/></td>
</tr>
</tbody>
</table>
<table summary="Distribution of space-group types in the hexagonal crystal family" width="98%" style="margin-left: auto; margin-right: auto; border:1px solid #55aa55; border-radius: 5px;">
<thead valign="top">
<tr>
<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="bottom"><span class="size2">Crystal system</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="2" colspan="1" align="left" valign="bottom"><span class="size2">Geometric crystal class</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="2" align="left" valign="bottom"><span class="size2">Lattice system</span></th></tr>
<tr>
<th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Hexagonal</span></th><th bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="bottom"><span class="size2">Rhombohedral</span></th></tr>
</thead>
<tbody valign="top">
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Hexagonal</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6/<span class="it"><i>mmm</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>6/<span class="it"><i>mmm</i></span>, <span class="it"><i>P</i></span>6/<span class="it"><i>mcc</i></span>, <img src="/teximages/acch1o3/acch1o3fi1096.svg" alt="[P6_3/mcm]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1097.svg" alt="[P6_3/mmc]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o2/abch2o2fi100.svg" alt="[\bar{6}2m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch4o3/abch4o3fi1390.svg" alt="[P\bar{6}m2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch4o1/abch4o1fi182.svg" alt="[P\bar{6}c2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch4o3/abch4o3fi356.svg" alt="[P\bar{6}2m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch4o1/abch4o1fi189.svg" alt="[P\bar{6}2c]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6<span class="it"><i>mm</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>6<span class="it"><i>mm</i></span>, <span class="it"><i>P</i></span>6<span class="it"><i>cc</i></span>, <img src="/teximages/acch1o3/acch1o3fi1103.svg" alt="[P6_3cm]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1104.svg" alt="[P6_3mc]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">622 </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>622, <img src="/teximages/acch1o3/acch1o3fi1105.svg" alt="[P6_122]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1106.svg" alt="[P6_522 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi662.svg" alt="[P6_222]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi661.svg" alt="[P6_422]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1109.svg" alt="[P6_322 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;" loading="lazy"/></span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6/<span class="it"><i>m</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>6/<span class="it"><i>m</i></span>, <img src="/teximages/acch1o3/acch1o3fi1110.svg" alt="[P6_3/m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.988792pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch1o4/abch1o4fi130.svg" alt="[\bar{6}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch4o1/abch4o1fi156.svg" alt="[P\bar{6}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">6 </span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>6, <img src="/teximages/acch1o3/acch1o3fi1113.svg" alt="[P6_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1114.svg" alt="[P6_5]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1115.svg" alt="[P6_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1116.svg" alt="[P6_4]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1117.svg" alt="[P6_3]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.904428pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style=" border-bottom:1px solid #55aa55;" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">Trigonal </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o1/abch2o1fi2.svg" alt="[\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch4o3/abch4o3fi369.svg" alt="[P\bar{3}1m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch4o3/abch4o3fi328.svg" alt="[P\bar{3}1c]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch4o3/abch4o3fi1315.svg" alt="[P\bar{3}m1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abch4o3/abch4o3fi343.svg" alt="[P\bar{3}c1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abpre6/abpre6fi12.svg" alt="[R\bar{3}m]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/>, <img src="/teximages/abpre6/abpre6fi13.svg" alt="[R\bar{3}c]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">3<span class="it"><i>m</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>3<span class="it"><i>m</i></span>1, <span class="it"><i>P</i></span>31<span class="it"><i>m</i></span>, <span class="it"><i>P</i></span>3<span class="it"><i>c</i></span>1, <span class="it"><i>P</i></span>31<span class="it"><i>c</i></span> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>R</i></span>3<span class="it"><i>m</i></span>, <span class="it"><i>R</i></span>3<span class="it"><i>c</i></span> </span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">32 </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>312, <span class="it"><i>P</i></span>321, <img src="/teximages/acch1o3/acch1o3fi1125.svg" alt="[P3_112 ]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi659.svg" alt="[P3_121]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1127.svg" alt="[P3_212]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi660.svg" alt="[P3_221]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>R</i></span>32 </span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch1o4/abch1o4fi128.svg" alt="[\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o2/abch2o2fi390.svg" alt="[P\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><img src="/teximages/abch2o2/abch2o2fi5.svg" alt="[R\bar{3}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.166746999999999pt;" loading="lazy"/> </span></td>
</tr>
<tr>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">&#160;</span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2">3 </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>P</i></span>3, <img src="/teximages/acch1o3/acch1o3fi1132.svg" alt="[P3_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/>, <img src="/teximages/acch1o3/acch1o3fi1133.svg" alt="[P3_2]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/> </span></td>
<td bgcolor="#FFFFFF" style="" rowspan="1" colspan="1" align="left" valign="top"><span class="size2"><span class="it"><i>R</i></span>3 </span></td>
</tr>
</tbody>
</table>
</td>
</tr>
</tbody>
</table>
</div>
<caption><span class="size2">Distribution of space-group types in the hexagonal crystal family<indexg><index type="s" significance="standard" id="acch1o3index00131">hexagonal crystal family<index type="s" significance="standard" id="acch1o3index00132">distribution of space-group types in</index></index></indexg></span></caption>
<short-tbcaption><span class="size2">Distribution of space-group types in the hexagonal crystal family<indexg><index type="s" significance="standard" id="acch1o3index00131">hexagonal crystal family<index type="s" significance="standard" id="acch1o3index00132">distribution of space-group types in</index></index></indexg></span></short-tbcaption>
</tablewrap>
</p>
</div>
</div>
</div>
</subch></bdy>
<bm>
<bibl>
<bb id="bb1"><glink>Armstrong%2C%20M.%20A.%20%281997%29.%20Groups%20and%20Symmetry.%20New%20York%3A%20Springer.</glink><bbau index="Armstrong, M. A.">Armstrong, M. A.</bbau> (1997). <article-title>Groups and Symmetry</article-title>. New York: Springer.</bb><bb id="bb2"><glink>Bieberbach%2C%20L.%20%281911%29.%20%26%23220%3Bber%20die%20Bewegungsgruppen%20der%20Euklidischen%20R%26%23228%3Bume.%20%28Erste%20Abhandlung%29.%20Math.%20Ann.%2070%2C%20297%26%238211%3B336.</glink><bbau index="Bieberbach, L.">Bieberbach, L.</bbau> (1911). <article-title>&#220;ber die Bewegungsgruppen der Euklidischen R&#228;ume. (Erste Abhandlung)</article-title>. <span class="it"><i>Math. Ann.</i></span> <span class="b"><b>70</b></span>, 297&#8211;336.</bb><bb id="bb3"><glink>Bieberbach%2C%20L.%20%281912%29.%20%26%23220%3Bber%20die%20Bewegungsgruppen%20der%20Euklidischen%20R%26%23228%3Bume.%20%28Zweite%20Abhandlung%29.%20Die%20Gruppen%20mit%20einem%20endlichen%20Fundamentalbereich.%20Math.%20Ann.%2072%2C%20400%26%238211%3B412.%20</glink><bbau index="Bieberbach, L.">Bieberbach, L.</bbau> (1912). <article-title>&#220;ber die Bewegungsgruppen der Euklidischen R&#228;ume. (Zweite Abhandlung). Die Gruppen mit einem endlichen Fundamentalbereich</article-title>. <span class="it"><i>Math. Ann.</i></span> <span class="b"><b>72</b></span>, 400&#8211;412. </bb><bb id="bb4"><glink>Minkowski%2C%20H.%20%281887%29.%20Zur%20Theorie%20der%20positiven%20quadratischen%20Formen.%20J.%20Reine%20Angew.%20Math.%20101%2C%20196%26%238211%3B202.</glink><bbau index="Minkowski, H.">Minkowski, H.</bbau> (1887). <span class="it"><i>Zur Theorie der positiven quadratischen Formen.</i></span> <span class="it"><i>J. Reine Angew. Math.</i></span> <span class="b"><b>101</b></span>, 196&#8211;202.</bb><bb id="bb5"><glink>Wolff%2C%20P.%20M.%20de%2C%20Belov%2C%20N.%20V.%2C%20Bertaut%2C%20E.%20F.%2C%20Buerger%2C%20M.%20J.%2C%20Donnay%2C%20J.%20D.%20H.%2C%20Fischer%2C%20W.%2C%20Hahn%2C%20Th.%2C%20Koptsik%2C%20V.%20A.%2C%20Mackay%2C%20A.%20L.%2C%20Wondratschek%2C%20H.%2C%20Wilson%2C%20A.%20J.%20C.%20%26%2338%3B%20Abrahams%2C%20S.%20C.%20%281985%29.%20Nomenclature%20for%20crystal%20families%2C%20Bravais-lattice%20types%20and%20arithmetic%20classes.%20Report%20of%20the%20International%20Union%20of%20Crystallography%20Ad-Hoc%20Committee%20on%20the%20Nomenclature%20of%20Symmetry.%20Acta%20Cryst.%20A41%2C%20278%26%238211%3B280.</glink><bbau index="de Wolff, P. M.">Wolff, P. M. de</bbau>, <bbau index="Belov, N. V.">Belov, N. V.</bbau>, <bbau index="Bertaut, E. F.">Bertaut, E. F.</bbau>, <bbau index="Buerger, M. J.">Buerger, M. J.</bbau>, <bbau index="Donnay, J. D. H.">Donnay, J. D. H.</bbau>, <bbau index="Fischer, W.">Fischer, W.</bbau>, <bbau index="Hahn, Th.">Hahn, Th.</bbau>, <bbau index="Koptsik, V. A.">Koptsik, V. A.</bbau>, <bbau index="Mackay, A. L.">Mackay, A. L.</bbau>, <bbau index="Wondratschek, H.">Wondratschek, H.</bbau>, <bbau index="Wilson, A. J. C.">Wilson, A. J. C.</bbau> &amp; <bbau index="Abrahams, S. C.">Abrahams, S. C.</bbau> (1985). <article-title>Nomenclature for crystal families, Bravais-lattice types and arithmetic classes. Report of the International Union of Crystallography Ad-Hoc Committee on the Nomenclature of Symmetry</article-title>. <span class="it"><i>Acta Cryst.</i></span> A<span class="b"><b>41</b></span>, 278&#8211;280.</bb></bibl>
</bm>
<figsection>
<bigfig id="fig1o3o2o1" fignum="1.3.2.1">
<div class="chfigure"><table summary="Figure 1.3.2.1" border="1" bgcolor="#ddeedd" width="100%">
<tbody>
<tr>
<td align="center">
<img src="/figures/Acfig1o3o2o1.gif" alt="[Figure 1.3.2.1]"/>
<br/>
</td>
</tr>
<tr>
<td>
<span class="size3"><b><a name="fig1o3o2o1">Figure 1.3.2.1</a></b></span>
<p>Conventional basis <img src="/teximages/abch15o2/abch15o2fi1476.svg" alt="[{\bf a}, {\bf b}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> and a non-conventional basis <img src="/teximages/acch1o3/acch1o3fi58.svg" alt="[{\bf a}', {\bf b}']" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.307348pt;" loading="lazy"/> for the square lattice.</p></td>
</tr>
</tbody>
</table>
<br/>
</div>
</bigfig>
<bigfig id="fig1o3o2o2" fignum="1.3.2.2">
<div class="chfigure"><table summary="Figure 1.3.2.2" border="1" bgcolor="#ddeedd" width="100%">
<tbody>
<tr>
<td align="center">
<img src="/figures/Acfig1o3o2o2.gif" alt="[Figure 1.3.2.2]"/>
<br/>
</td>
</tr>
<tr>
<td>
<span class="size3"><b><a name="fig1o3o2o2">Figure 1.3.2.2</a></b></span>
<p>Vorono&#239; domains and primitive unit cells for a rectangular lattice (<span class="it"><i>a</i></span>) and an oblique lattice (<span class="it"><i>b</i></span>).</p></td>
</tr>
</tbody>
</table>
<br/>
</div>
</bigfig>
<bigfig id="fig1o3o2o3" fignum="1.3.2.3">
<div class="chfigure"><table summary="Figure 1.3.2.3" border="1" bgcolor="#ddeedd" width="100%">
<tbody>
<tr>
<td align="center">
<img src="/figures/Acfig1o3o2o3.gif" alt="[Figure 1.3.2.3]"/>
<br/>
</td>
</tr>
<tr>
<td>
<span class="size3"><b><a name="fig1o3o2o3">Figure 1.3.2.3</a></b></span>
<p>Primitive rectangular lattice (only the filled nodes) and centred rectangular lattice (filled and open nodes).</p></td>
</tr>
</tbody>
</table>
<br/>
</div>
</bigfig>
<bigfig id="fig1o3o2o4" fignum="1.3.2.4">
<div class="chfigure"><table summary="Figure 1.3.2.4" border="1" bgcolor="#ddeedd" width="100%">
<tbody>
<tr>
<td align="center">
<img src="/figures/Acfig1o3o2o4.gif" alt="[Figure 1.3.2.4]"/>
<br/>
</td>
</tr>
<tr>
<td>
<span class="size3"><b><a name="fig1o3o2o4">Figure 1.3.2.4</a></b></span>
<p>Primitive cell (dashed line) and centred cell (solid lines) for the centred rectangular lattice.</p></td>
</tr>
</tbody>
</table>
<br/>
</div>
</bigfig>
<bigfig id="fig1o3o4o1" fignum="1.3.4.1">
<div class="chfigure"><table summary="Figure 1.3.4.1" border="1" bgcolor="#ddeedd" width="100%">
<tbody>
<tr>
<td align="center">
<img src="/figures/Acfig1o3o4o1.gif" alt="[Figure 1.3.4.1]"/>
<br/>
</td>
</tr>
<tr>
<td>
<span class="size3"><b><a name="fig1o3o4o1">Figure 1.3.4.1</a></b></span>
<p>Classification levels for three-dimensional space groups.</p></td>
</tr>
</tbody>
</table>
<br/>
</div>
</bigfig>
<bigfig id="fig1o3o4o2" fignum="1.3.4.2">
<div class="chfigure"><table summary="Figure 1.3.4.2" border="1" bgcolor="#ddeedd" width="100%">
<tbody>
<tr>
<td align="center">
<img src="/figures/Acfig1o3o4o2.gif" alt="[Figure 1.3.4.2]"/>
<br/>
</td>
</tr>
<tr>
<td>
<span class="size3"><b><a name="fig1o3o4o2">Figure 1.3.4.2</a></b></span>
<p>Space-group diagram of <img src="/teximages/acch1o3/acch1o3fi592.svg" alt="[I4_1]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -1.793264pt;" loading="lazy"/> (left) and its reflection in the plane <span class="it"><i>z</i></span> = 0 (right).</p></td>
</tr>
</tbody>
</table>
<br/>
</div>
</bigfig>
</figsection>
<fnsection>
<fn id="fn1" number="1">
<p>The trace of a matrix is the sum of its diagonal entries.</p>
</fn>
<fn id="fn2" number="2">
<p>A symmetric matrix <img src="/teximages/acch1o3/acch1o3fi318.svg" alt="[{\bi G}]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.214388999999999pt;" loading="lazy"/> is <span class="it"><i>positive definite</i></span> if <img src="/teximages/acch1o3/acch1o3fi802.svg" alt="[{\bf v}^{\rm T} \cdot {\bi G} \cdot {\bf v}\,\gt\, 0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -0.478206999999996pt;" loading="lazy"/> for every vector <img src="/teximages/acch1o3/acch1o3fi803.svg" alt="[{\bf v} \neq 0]" class="img_align_bottom" style="position: relative; display: inline; padding-top: 0px; padding-bottom: 0px; vertical-align: -2.582317pt;" loading="lazy"/>.</p>
</fn>
</fnsection>
<indexes>
   <entry number="1">
      <term level="1">
         <level1>affine space</level1>
         <link significance="standard" section="1" volid="Ac" secid="1.3.1" secido="1o3o1" id="acch1o3index00002" indexid="index00002" chnumo="1o3" type="s"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>arithmetic crystal class</level1>
         <link secid="1.3.4.4.1" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00114" indexid="index00114" secido="1o3o4o4o1"/>
      </term>
   </entry>
   <entry number="3">
      <term level="1">
         <level1>automorphism group</level1>
         <link secid="1.3.3.1" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00087" indexid="index00087" secido="1o3o3o1"/>
         <link chnumo="1o3" type="s" secido="1o3o3o1" id="acch1o3index00123" indexid="index00123" volid="Ac" secid="1.3.3.1" significance="standard" section="2"/>
         <link secido="1o3o3o2" indexid="index00124" id="acch1o3index00124" type="s" chnumo="1o3" significance="standard" section="2" volid="Ac" secid="1.3.3.2"/>
      </term>
   </entry>
   <entry number="4">
      <term level="1">
         <level1>basis</level1>
         <link type="s" chnumo="1o3" indexid="index00024" id="acch1o3index00024" secido="1o3o2o1" secid="1.3.2.1" volid="Ac" section="1" significance="standard"/>
      </term>
      <term level="2">
         <index id="acch1o3index00046" significance="standard" type="s">conventional</index>
         <link section="1" significance="standard" secid="1.3.2.4" volid="Ac" id="acch1o3index00046" indexid="index00046" secido="1o3o2o4" chnumo="1o3" type="s"/>
      </term>
      <term level="2">
         <index id="acch1o3index00049" significance="standard" type="s">primitive</index>
         <link section="1" significance="standard" secid="1.3.2.4" volid="Ac" indexid="index00049" id="acch1o3index00049" secido="1o3o2o4" type="s" chnumo="1o3"/>
      </term>
      <term level="2">
         <index id="acch1o3index00081" significance="standard" type="s">reciprocal</index>
         <link volid="Ac" secid="1.3.2.5" significance="standard" section="1" chnumo="1o3" type="s" secido="1o3o2o5" id="acch1o3index00081" indexid="index00081"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>basis transformation</level1>
         <link type="s" chnumo="1o3" indexid="index00028" id="acch1o3index00028" secido="1o3o2o2" secid="1.3.2.2" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Bieberbach theorem</level1>
         <link id="acch1o3index00105" indexid="index00105" secido="1o3o4o1" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.4.1" volid="Ac"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Bravais arithmetic crystal class</level1>
         <link volid="Ac" secid="1.3.4.4.1" significance="standard" section="1" chnumo="1o3" type="s" secido="1o3o4o4o1" id="acch1o3index00115" indexid="index00115"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Bravais class</level1>
         <link volid="Ac" secid="1.3.4.3" significance="standard" section="1" type="s" chnumo="1o3" secido="1o3o4o3" indexid="index00109" id="acch1o3index00109"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Bravais flock</level1>
         <link significance="standard" section="1" volid="Ac" secid="1.3.4.4.1" secido="1o3o4o4o1" indexid="index00116" id="acch1o3index00116" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>Bravais group</level1>
         <link chnumo="1o3" type="s" id="acch1o3index00088" indexid="index00088" secido="1o3o3o1" secid="1.3.3.1" volid="Ac" section="1" significance="standard"/>
         <link chnumo="1o3" type="s" secido="1o3o4o3" id="acch1o3index00110" indexid="index00110" volid="Ac" secid="1.3.4.3" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>Bravais type of lattice</level1>
         <link volid="Ac" secid="1.3.4.3" significance="standard" section="1" type="s" chnumo="1o3" secido="1o3o4o3" indexid="index00108" id="acch1o3index00108"/>
         <link section="2" significance="standard" secid="1.3.4.1" volid="Ac" indexid="index00127" id="acch1o3index00127" secido="1o3o4o1" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Brillouin zone</level1>
         <link id="acch1o3index00037" indexid="index00037" secido="1o3o2o3" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.2.3" volid="Ac"/>
      </term>
   </entry>
   <entry number="5">
      <term level="1">
         <level1>cell</level1>
      </term>
      <term level="2">
         <index id="acch1o3index00061" significance="standard" type="s">centred</index>
         <link indexid="index00061" id="acch1o3index00061" secido="1o3o2o4" type="s" chnumo="1o3" section="1" significance="standard" secid="1.3.2.4" volid="Ac"/>
      </term>
      <term level="2">
         <index id="acch1o3index00067" significance="standard" type="s">conventional</index>
         <link section="1" significance="standard" secid="1.3.2.4" volid="Ac" id="acch1o3index00067" indexid="index00067" secido="1o3o2o4" chnumo="1o3" type="s"/>
         <link significance="standard" section="1" volid="Ac" secid="1.3.2.4" secido="1o3o2o4" indexid="index00072" id="acch1o3index00072" type="s" chnumo="1o3"/>
      </term>
      <term level="2">
         <index id="acch1o3index00064" significance="standard" type="s">multiple</index>
         <link chnumo="1o3" type="s" secido="1o3o2o4" id="acch1o3index00064" indexid="index00064" volid="Ac" secid="1.3.2.4" significance="standard" section="1"/>
      </term>
      <term level="2">
         <index id="acch1o3index00056" significance="standard" type="s">primitive</index>
         <link type="s" chnumo="1o3" indexid="index00056" id="acch1o3index00056" secido="1o3o2o4" secid="1.3.2.4" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>cell parameters</level1>
         <link volid="Ac" secid="1.3.2.2" significance="standard" section="1" type="s" chnumo="1o3" secido="1o3o2o2" indexid="index00030" id="acch1o3index00030"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>centred cell</level1>
         <link volid="Ac" secid="1.3.2.4" significance="standard" section="1" type="s" chnumo="1o3" secido="1o3o2o4" indexid="index00059" id="acch1o3index00059"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>centred lattice</level1>
         <link secid="1.3.2.4" volid="Ac" section="1" significance="standard" type="s" chnumo="1o3" indexid="index00038" id="acch1o3index00038" secido="1o3o2o4"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>centring vector</level1>
         <link volid="Ac" secid="1.3.2.4" significance="standard" section="1" type="s" chnumo="1o3" secido="1o3o2o4" indexid="index00050" id="acch1o3index00050"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>conventional basis</level1>
         <link secid="1.3.2.4" volid="Ac" section="1" significance="standard" type="s" chnumo="1o3" indexid="index00044" id="acch1o3index00044" secido="1o3o2o4"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>conventional cell</level1>
         <link type="s" chnumo="1o3" indexid="index00065" id="acch1o3index00065" secido="1o3o2o4" secid="1.3.2.4" volid="Ac" section="1" significance="standard"/>
         <link chnumo="1o3" type="s" secido="1o3o2o4" id="acch1o3index00070" indexid="index00070" volid="Ac" secid="1.3.2.4" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>conventional coordinate system</level1>
         <link chnumo="1o3" type="s" secido="1o3o4o4o4" id="acch1o3index00120" indexid="index00120" volid="Ac" secid="1.3.4.4.4" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>coordinates and coordinate triplets</level1>
         <link section="1" significance="standard" secid="1.3.2.1" volid="Ac" indexid="index00025" id="acch1o3index00025" secido="1o3o2o1" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>coordinate system</level1>
         <link chnumo="1o3" type="s" secido="1o3o2o2" id="acch1o3index00026" indexid="index00026" volid="Ac" secid="1.3.2.2" significance="standard" section="1"/>
      </term>
      <term level="2">
         <index id="acch1o3index00122" significance="standard" type="s">conventional</index>
         <link secid="1.3.4.4.4" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00122" indexid="index00122" secido="1o3o4o4o4"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>coset decomposition</level1>
         <link section="1" significance="standard" secid="1.3.3.2" volid="Ac" indexid="index00089" id="acch1o3index00089" secido="1o3o3o2" type="s" chnumo="1o3"/>
         <link chnumo="1o3" type="s" secido="1o3o3o3" id="acch1o3index00125" indexid="index00125" volid="Ac" secid="1.3.3.3" significance="standard" section="2"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>coset representatives</level1>
         <link secid="1.3.3.2" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00093" indexid="index00093" secido="1o3o3o2"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>crystal family</level1>
         <link type="s" chnumo="1o3" indexid="index00119" id="acch1o3index00119" secido="1o3o4o4o4" secid="1.3.4.4.4" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>crystallographic space group</level1>
         <link secido="1o3o1" indexid="index00008" id="acch1o3index00008" type="s" chnumo="1o3" significance="standard" section="1" volid="Ac" secid="1.3.1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>crystallographic space-group operation</level1>
         <link secido="1o3o1" id="acch1o3index00004" indexid="index00004" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.1"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>crystal system</level1>
         <link section="1" significance="standard" secid="1.3.4.4.3" volid="Ac" indexid="index00118" id="acch1o3index00118" secido="1o3o4o4o3" type="s" chnumo="1o3"/>
         <link secido="1o3o4o2" id="acch1o3index00129" indexid="index00129" chnumo="1o3" type="s" significance="standard" section="2" volid="Ac" secid="1.3.4.2"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Dirichlet domain</level1>
         <link section="1" significance="standard" secid="1.3.2.3" volid="Ac" id="acch1o3index00034" indexid="index00034" secido="1o3o2o3" chnumo="1o3" type="s"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>enantiomorphism</level1>
         <link type="s" chnumo="1o3" secido="1o3o4o1" indexid="index00106" id="acch1o3index00106" volid="Ac" secid="1.3.4.1" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>fundamental domain</level1>
         <link volid="Ac" secid="1.3.2.3" significance="standard" section="1" chnumo="1o3" type="s" secido="1o3o2o3" id="acch1o3index00032" indexid="index00032"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>geometric crystal class</level1>
         <link secid="1.3.4.2" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00107" indexid="index00107" secido="1o3o4o2"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>hexagonal crystal family</level1>
      </term>
      <term level="2">
         <index id="acch1o3index00132" significance="standard" type="s">distribution of space-group types in</index>
         <link significance="standard" section="2" volid="Ac" secid="1.3.4.3" secido="1o3o4o3" indexid="index00132" id="acch1o3index00132" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>holohedry</level1>
         <link type="s" chnumo="1o3" indexid="index00112" id="acch1o3index00112" secido="1o3o4o3" secid="1.3.4.3" volid="Ac" section="1" significance="standard"/>
         <link chnumo="1o3" type="s" id="acch1o3index00128" indexid="index00128" secido="1o3o4o1" secid="1.3.4.1" volid="Ac" section="2" significance="standard"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>homomorphism</level1>
         <link secido="1o3o3o1" id="acch1o3index00082" indexid="index00082" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.3.1"/>
      </term>
      <term level="2">
         <index id="acch1o3index00085" significance="standard" type="s">kernel of</index>
         <link type="s" chnumo="1o3" secido="1o3o3o1" indexid="index00085" id="acch1o3index00085" volid="Ac" secid="1.3.3.1" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>isometry</level1>
         <link secido="1o3o1" id="acch1o3index00001" indexid="index00001" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>kernel of a homomorphism</level1>
         <link section="1" significance="standard" secid="1.3.3.1" volid="Ac" indexid="index00083" id="acch1o3index00083" secido="1o3o3o1" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="5">
      <term level="1">
         <level1>lattice</level1>
         <link chnumo="1o3" type="s" id="acch1o3index00022" indexid="index00022" secido="1o3o2" secid="1.3.2" volid="Ac" section="1" significance="standard"/>
      </term>
      <term level="2">
         <index id="acch1o3index00043" significance="standard" type="s">centred</index>
         <link section="1" significance="standard" secid="1.3.2.4" volid="Ac" id="acch1o3index00043" indexid="index00043" secido="1o3o2o4" chnumo="1o3" type="s"/>
      </term>
      <term level="2">
         <index id="acch1o3index00041" significance="standard" type="s">primitive</index>
         <link secido="1o3o2o4" id="acch1o3index00041" indexid="index00041" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.2.4"/>
      </term>
      <term level="2">
         <index id="acch1o3index00078" significance="standard" type="s">reciprocal</index>
         <link secid="1.3.2.5" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00078" indexid="index00078" secido="1o3o2o5"/>
      </term>
      <term level="2">
         <index id="acch1o3index00075" significance="standard" type="s">rhombohedral</index>
         <link type="s" chnumo="1o3" secido="1o3o2o4" indexid="index00075" id="acch1o3index00075" volid="Ac" secid="1.3.2.4" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>lattice basis</level1>
         <link secido="1o3o2o1" id="acch1o3index00023" indexid="index00023" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.2.1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>lattice point group</level1>
         <link id="acch1o3index00113" indexid="index00113" secido="1o3o4o3" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.4.3" volid="Ac"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>lattice system</level1>
         <link chnumo="1o3" type="s" secido="1o3o4o4o2" id="acch1o3index00117" indexid="index00117" volid="Ac" secid="1.3.4.4.2" significance="standard" section="1"/>
         <link chnumo="1o3" type="s" id="acch1o3index00126" indexid="index00126" secido="1o3o4o1" secid="1.3.4.1" volid="Ac" section="2" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>linear part of a space-group operation</level1>
         <link secid="1.3.1" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00014" indexid="index00014" secido="1o3o1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>matrix&#8211;column pair</level1>
         <link id="acch1o3index00011" indexid="index00011" secido="1o3o1" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.1" volid="Ac"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>metric tensor</level1>
         <link secid="1.3.2.2" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00027" indexid="index00027" secido="1o3o2o2"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>multiple cell</level1>
         <link indexid="index00062" id="acch1o3index00062" secido="1o3o2o4" type="s" chnumo="1o3" section="1" significance="standard" secid="1.3.2.4" volid="Ac"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>non-symmorphic space groups</level1>
         <link chnumo="1o3" type="s" secido="1o3o3o3" id="acch1o3index00098" indexid="index00098" volid="Ac" secid="1.3.3.3" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>origin choice</level1>
         <link volid="Ac" secid="1.3.3.3" significance="standard" section="1" type="s" chnumo="1o3" secido="1o3o3o3" indexid="index00100" id="acch1o3index00100"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>point groups</level1>
         <link type="s" chnumo="1o3" indexid="index00021" id="acch1o3index00021" secido="1o3o1" secid="1.3.1" volid="Ac" section="1" significance="standard"/>
         <link section="1" significance="standard" secid="1.3.3.1" volid="Ac" id="acch1o3index00086" indexid="index00086" secido="1o3o3o1" chnumo="1o3" type="s"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>point-group types</level1>
         <link volid="Ac" secid="1.3.4.2" significance="standard" section="2" type="s" chnumo="1o3" secido="1o3o4o2" indexid="index00130" id="acch1o3index00130"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>primitive basis</level1>
         <link type="s" chnumo="1o3" indexid="index00047" id="acch1o3index00047" secido="1o3o2o4" secid="1.3.2.4" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>primitive cell</level1>
         <link secid="1.3.2.4" volid="Ac" section="1" significance="standard" type="s" chnumo="1o3" indexid="index00051" id="acch1o3index00051" secido="1o3o2o4"/>
         <link id="acch1o3index00054" indexid="index00054" secido="1o3o2o4" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.2.4" volid="Ac"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>primitive lattice</level1>
         <link significance="standard" section="1" volid="Ac" secid="1.3.2.4" secido="1o3o2o4" indexid="index00039" id="acch1o3index00039" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>reciprocal basis</level1>
         <link secido="1o3o2o5" id="acch1o3index00079" indexid="index00079" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.2.5"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>reciprocal lattice</level1>
         <link indexid="index00076" id="acch1o3index00076" secido="1o3o2o5" type="s" chnumo="1o3" section="1" significance="standard" secid="1.3.2.5" volid="Ac"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>rhombohedral lattice</level1>
         <link id="acch1o3index00073" indexid="index00073" secido="1o3o2o4" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.2.4" volid="Ac"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>site-symmetry group</level1>
         <link secid="1.3.3.3" volid="Ac" section="1" significance="standard" type="s" chnumo="1o3" indexid="index00101" id="acch1o3index00101" secido="1o3o3o3"/>
      </term>
   </entry>
   <entry number="3">
      <term level="1">
         <level1>space-group operation</level1>
      </term>
      <term level="2">
         <index id="acch1o3index00006" significance="standard" type="s">crystallographic</index>
         <link type="s" chnumo="1o3" secido="1o3o1" indexid="index00006" id="acch1o3index00006" volid="Ac" secid="1.3.1" significance="standard" section="1"/>
      </term>
      <term level="2">
         <index id="acch1o3index00013" significance="standard" type="s">linear part</index>
         <link significance="standard" section="1" volid="Ac" secid="1.3.1" secido="1o3o1" indexid="index00013" id="acch1o3index00013" type="s" chnumo="1o3"/>
      </term>
      <term level="2">
         <index id="acch1o3index00016" significance="standard" type="s">translation part</index>
         <link secid="1.3.1" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00016" indexid="index00016" secido="1o3o1"/>
      </term>
   </entry>
   <entry number="5">
      <term level="1">
         <level1>space groups</level1>
         <link indexid="index00007" id="acch1o3index00007" secido="1o3o1" type="s" chnumo="1o3" section="1" significance="standard" secid="1.3.1" volid="Ac"/>
      </term>
      <term level="2">
         <index id="acch1o3index00103" significance="standard" type="s">classification of</index>
         <link secido="1o3o4" indexid="index00103" id="acch1o3index00103" type="s" chnumo="1o3" significance="standard" section="1" volid="Ac" secid="1.3.4"/>
      </term>
      <term level="2">
         <index id="acch1o3index00010" significance="standard" type="s">crystallographic</index>
         <link secid="1.3.1" volid="Ac" section="1" significance="standard" type="s" chnumo="1o3" indexid="index00010" id="acch1o3index00010" secido="1o3o1"/>
      </term>
      <term level="2">
         <index id="acch1o3index00097" significance="standard" type="s">non-symmorphic</index>
         <link secido="1o3o3o3" id="acch1o3index00097" indexid="index00097" chnumo="1o3" type="s" significance="standard" section="1" volid="Ac" secid="1.3.3.3"/>
      </term>
      <term level="2">
         <index id="acch1o3index00095" significance="standard" type="s">symmorphic</index>
         <link chnumo="1o3" type="s" id="acch1o3index00095" indexid="index00095" secido="1o3o3o3" secid="1.3.3.3" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>space-group types</level1>
         <link chnumo="1o3" type="s" secido="1o3o4o1" id="acch1o3index00104" indexid="index00104" volid="Ac" secid="1.3.4.1" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>specialized metrics</level1>
         <link volid="Ac" secid="1.3.4.3" significance="standard" section="1" chnumo="1o3" type="s" secido="1o3o4o3" id="acch1o3index00111" indexid="index00111"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>subgroups</level1>
      </term>
      <term level="2">
         <index id="acch1o3index00020" significance="standard" type="s">translation subgroup</index>
         <link indexid="index00020" id="acch1o3index00020" secido="1o3o1" type="s" chnumo="1o3" section="1" significance="standard" secid="1.3.1" volid="Ac"/>
         <link significance="standard" section="1" volid="Ac" secid="1.3.3.2" secido="1o3o3o2" indexid="index00092" id="acch1o3index00092" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>symmorphic space groups</level1>
         <link significance="standard" section="1" volid="Ac" secid="1.3.3.3" secido="1o3o3o3" indexid="index00099" id="acch1o3index00099" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>transformation of basis</level1>
         <link significance="standard" section="1" volid="Ac" secid="1.3.2.2" secido="1o3o2o2" indexid="index00029" id="acch1o3index00029" type="s" chnumo="1o3"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>translation part of a space-group operation</level1>
         <link significance="standard" section="1" volid="Ac" secid="1.3.1" secido="1o3o1" id="acch1o3index00017" indexid="index00017" chnumo="1o3" type="s"/>
      </term>
   </entry>
   <entry number="2">
      <term level="1">
         <level1>translation subgroup</level1>
         <link id="acch1o3index00018" indexid="index00018" secido="1o3o1" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.1" volid="Ac"/>
         <link type="s" chnumo="1o3" secido="1o3o3o2" indexid="index00090" id="acch1o3index00090" volid="Ac" secid="1.3.3.2" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="4">
      <term level="1">
         <level1>unit cell</level1>
         <link id="acch1o3index00031" indexid="index00031" secido="1o3o2o3" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.2.3" volid="Ac"/>
      </term>
      <term level="2">
         <index id="acch1o3index00058" significance="standard" type="s">centred</index>
         <link type="s" chnumo="1o3" secido="1o3o2o4" indexid="index00058" id="acch1o3index00058" volid="Ac" secid="1.3.2.4" significance="standard" section="1"/>
      </term>
      <term level="2">
         <index id="acch1o3index00069" significance="standard" type="s">conventional</index>
         <link id="acch1o3index00069" indexid="index00069" secido="1o3o2o4" chnumo="1o3" type="s" section="1" significance="standard" secid="1.3.2.4" volid="Ac"/>
      </term>
      <term level="2">
         <index id="acch1o3index00053" significance="standard" type="s">primitive</index>
         <link type="s" chnumo="1o3" secido="1o3o2o4" indexid="index00053" id="acch1o3index00053" volid="Ac" secid="1.3.2.4" significance="standard" section="1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>vector space</level1>
         <link secid="1.3.1" volid="Ac" section="1" significance="standard" chnumo="1o3" type="s" id="acch1o3index00003" indexid="index00003" secido="1o3o1"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Vorono&#239; domain</level1>
         <link type="s" chnumo="1o3" indexid="index00033" id="acch1o3index00033" secido="1o3o2o3" secid="1.3.2.3" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>Wigner&#8211;Seitz cell</level1>
         <link type="s" chnumo="1o3" indexid="index00035" id="acch1o3index00035" secido="1o3o2o3" secid="1.3.2.3" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
   <entry number="1">
      <term level="1">
         <level1>
            <span class="it">
               <i>Wirkungsbereich</i>
            </span> (domain of influence)</level1>
         <link type="s" chnumo="1o3" indexid="index00036" id="acch1o3index00036" secido="1o3o2o3" secid="1.3.2.3" volid="Ac" section="1" significance="standard"/>
      </term>
   </entry>
</indexes>
</wrap>