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MATHEMATICAL CRYSTALLOGRAPHY A N INTRODUCTION TO THE MATHEMATICAL FOUNDATIONS OF CRYSTALLOGRAPHY T H E REVISED EDITION OF VOLUME 1 5 R E V I E W S IN M I N E R A L O G Y
AUTHORS:
M . B. BOISEN, JR. DEPARTMENT OF MATHEMATICS
G . V . GIBBS DEPARTMENT OF GEOLOGICAL SCIENCES
Virginia Polytechnic Institute & State University Blacksburg, Virginia 24061
SERIES EDITOR: PAUL H . RIBBE DEPARTMENT OF GEOLOGICAL SCIENCES
Virginia Polytechnic Institute & State University Blacksburg, Virginia 24061 MINERALOGICAL SOCIETY OF AMERICA WASHINGTON, D.C.
COPYRIGHT: FIRST EDITION 1985 REVISED EDITION 1990 MINERALOGICAL
SOCIETY
of
AMERICA
Printed by BookCrafters, Inc., Chelsea, Michigan 48118 REVIEWS in MINERALOGY (Formerly: SHORT COURSE NOTES) ISSN 0275-0279 VOLUME 15, Revised Edition MATHEMATICAL CRYSTALLOGRAPHY ISBN 0-939950-26-X ADDITIONAL COPIES of this volume as well as those listed below may be obtained from the MlNERALOGICAL SOCIETY OF AMERICA 1625 I Street N.W., Suite 414, Washington, D.C. 20006 U.S.A. Volume 1: Sulfide Mineralogy, 1974; P. H. Ribbe, Ed. 284 pp. Six chapters on the structures of sulfides and sulfosatts; the crystal chemistry and chemical bonding of sulfides, synthesis, phase equilibria, and petrology. I S B N # 0-939950-01-4. Volume 2: Feldspar Mineralogy, 2nd Edition, 1983; P. H. Ribbe, Ed. 362 pp. $17. Thirteen chapters on feldspar chemistry, structure and nomenclature; Al.Si order/disorder in relation to domain textures, diffraction patterns, lattice parameters and optical properties; determinative methods; subsolidus phase relations, microstructures, kinetics and mechanisms of exsolution, and diffusion; color and interference colors; chemical properties; deformation. I S B N # 0-939950-14-6. Volume 4: Mineralogy and Geology of Natural Zeolites, 1977; F. A. Mumpton, Ed. 232 pp. Ten chapters on the crystal chemistry and structure of natural zeolites, their occurrence in sedimentary and low-grade metamorphic rocks and closed hydrologic systems, their commercial properties and utilization. I S B N * 0-939950-04-9. Volume 5: Orttiosiiicates, 2nd Edition, 1982; P. H. Ribbe, Ed. 450 pp. Liebau's "Classification of Silicates" plus 12 chapters on silicate garnets, olivines, spinels and humites; zircon and the actinide orthosilicates; titanite (sphene), chloritoid, staurolite, the aluminum silicates, topaz, and scores of miscellaneous orthosilicates. Indexed. I S B N # 0-939950-13-8. Volume 8: Marine Minerals, 1979; R. G. Bums, Ed. 380 pp. Ten chapters on manganese and iron oxides, the silica polymorphs, zeolites, day minerals, marine phosphorites, barites and placer minerals; evaporite mineralogy and chemistry. I S B N # 0-939950-06-5. Volume 7: Pyroxenes, 1980; C. T. Prewrtt, Ed. 525 pp. Nine chapters on pyroxene crystal chemistry, spectroscopy, phase equilibria, subsolidus phenomena and thermodynamics; composition and mineralogy of terrestrial, lunar, and meteoritic pyroxenes. I S 8 N # 0-939950-07-3. Volume 8: Kinetics of Geochemlcal Processes, 1981; A. C. Lasaga and R. J. Kirkpatrlck, Eds. 398 pp. Eight chapters on transition state theory and the rate laws of chemical reactions; kinetics of weathering, diagenesis, igneous crystallization and geochemical cycles; diffusion in electrolytes; irreversible thermodynamics. I S B N # 0-939950-06-1. Volume 9A: Amphibotes and Other Hydrous Pyriboies—Mineralogy, 1981; D. R. Veblen, Ed. 372 pp. Seven chapters on biopyribole mineralogy and polysomatism; the crystal chemistry, structures and spectroscopy of amphiboles; subsolidus relations; amphibole and serpentine asbestos—mineralogy, occurrences, and health hazards. I S B N # 0-939950-10-3. Volume 9B: Amphiboles: Petrology and Experimental Phaae Relations, 1982; D. R. Veblen and P. H. Ribbe, Eds. 390 pp. Three chapters on phase relations of metamorphic amphiboles (occurrences and theory); igneous amphiboles; experimental studies. I S B N # 0-939950-11-1. Volume 10: Characterization of Metamorphism through Mineral Equilibria, 1982; J. M. Ferry, Ed. 397 pp. Nine chapters on an algebraic approach to composition and reaction spaces and their manipulation; the Gibbs' formulation of phase equilibria; geologic thermobarometry; buffering, infiltration, isotope fractionation, compositional zoning and inclusions; characterization of metamorphic fluids. I S B N # 0-939950-12-X. Volume 11: Carbonates: Mineralogy and Chemistry, 1983; R. J. Reader, Ed. 394 pp. Nine chapters on crystal chemistry, polymorphism, microstructures and phase relations of the rbombohedral and orthorhombic carbonates; the kinetics of CaCO, dissolution and precipitation; trace elements and isotopes in sedimentary carbonates; the occurrence, solubility and solid solution behavior of Mg-caldtes; geologic thermobarometry using metamorphic carbonates. I S B N # 0-939950-15-4.
Volume 12: Fluid Inclusions, 1984; by E. Roedder. 844 pp. Nineteen chapters providing an introduction to studies of aN types of fluid inclusions, gas, liquid or melt, trapped in materials from the earth and space, and their application to the understanding of geological processes. I S B N # 0-939950-16-2. Volume 13: Micas, 1984; S. W. Bailey, Ed. 584 pp. Thirteen chapters on structures, crystal chemistry, spectroscopic and optical properties, occurrences, paragenesis, geochemistry and petrology of micas. I S B N # 0-93995^17-0. Volume 14: Microscopic to Macroscopic: Atomic Environments to Mineral Thermodynamics, 1985; S. W. Kleffer and A. Navrotsky, Eds. 428 pp. Eleven chapters attempt to answer the question, "What minerals exist under given constraints of pressure, temperature, and composition, and why?" Includes worked examples at the end of some chapters. I S B N # 0-93995016-9. Volume 15: Mathematical Crystallography, 1985; by M. B. Bolsen, Jr. and G. V. Glbbs. 408 pp.4 p A matrix and group theoretic treatment of the point groups, Bravais lattices, and space groups presented with numerous examples and problem sets, Including solutions to common crystallography problems involving the geometry and symmetry of crystal structures. I S B N # 0-93995019-7. Volume 18: Stable Isotopes in High Temperature Geological Processes, 1988; J. W. Valley, H. P. Taylor, Jr., and J. R. O'Neil, Eds. 570 pp. Starting with the theoretical, kinetic and experimental aspects of isotopic fractionation, 14 chapters deal with stable isotopes in the early solar system, in the mantle, and in the igneous and metamorphic rocks and ore deposits, as well as in magmatic volatiles, natural water, seawater, and in meteoric-hydrothermal systems. ISBN #0-939950-20-0. Volume 17: Thermodynamic Modelling of Geological Materials: Minerals, Fluids, Melts, 1987; H. P. Eugster and 1. S E. Carmlchael, Eds. 500 pp. Thermodynamic analysis of phase equilibria in simple and multi-component mineral systems, and thermodynamic models of crystalline solutions, igneous gases and fluid, ore fluid, metamorphic fluids, and silicate melts, are the subjects of this 14-chapter volume. ISBN # 0-939950-21-9. Volume 18: Spectroscopic Methods in Mineralogy and Geology, 1988; F. C. Hawthorne, Ed. 898 pp. Detailed explanations and encyclopedic discussion of applications of spectroscopies of major importance to earth sciences. Included are IR, optical, Raman, Mossbauer, M A S NMR, EXAFS, XANES, EPR, Auger, XPS, luminescence, XRF, PIXE, R B S and EELS. ISBN # ->-939f 0-939950-22-7. Volume 19: Hydrous Phyllosillcates (exclusive of micas), 1988; S. W. Bailey, Ed. 898 pp. Seventeen chapters covering the crystal structures, crystal chemistry, serpentine, kaolin, talc, pyrophyllite, chlorite, vermiculite, smectite, mixed-layer, sepiolite, palygorskite, and modulated type hydrous phyllosilicate minerals. Volume 20: Modem Powder Diffraction, 1989; D. L Blah and J. E. Post, Eds. The principles, instrumentation, experimental procedures, and computer analysis of X-ray (synchrotron) and neutron powder diffraction, with chapters on sample preparation, quantitative analysis, profile fitting, and Rletveld refinement of crystal structures. ISBN # 6-939950-24-3. Volume 21: Geochemistry and Mineralogy of Rare Earth Elements, 1989; B. R. Upln and G. A. McKay, Eds.
REVIEWS IN MINERALOGY Foreword t o Volume 15 M A T H E M A T I C A L C R Y S T A L L O G R A P H Y represents a new direction for the Reviews in Mineralogy series. This text book is not a review volume in any sense of the term, but in fact it is, as its subtitle suggests, "An Introduction to the Mathematical Foundations of Crystallography." Written by a mathematician, M. B. Boisen, Jr., and a mineralogist, G. V. Gibbs, Volume 15 was carefully prepared and illustrated over a period of several years. It contains numerous worked examples, in addition to problem sets (many with answers) for the reader to solve. The book was first introduced at a Short Course of the same title in conjunction with the annual meetings of the Mineralogical Society of America and the Geological Society of America at Orlando, Florida, October 24-27, 1985. Boisen and Gibbs instructed 35 participants with the assistance of E. Patrick Meagher, (University of British Columbia), James W. Downs (Ohio State University), and Bryan C. Chakoumakos (University of New Mexico), who led the computer-based laboratory sessions. Paul H. Ribbe Series Editor Blacksburg, VA 9/13/85 - a Friday
Preface to t h e R e v i s e d Edition of M a t h e m a t i c a l Crystallography In the Revised Edition we have corrected the errors, misprints and omissions that we have found and our students and other users have kindly pointed out to us. In particular, we are pleased to thank our bright and talented students K.M. Whalen, K.L. Bartelmehs, L.A. Buterakos, V.K Chapman, B.C. Chakoumakos, J.W Downs and R.T. Downs for bringing some of these errors to our attention. The Revised Edition also includes a more comprehensive index and a set of solutions for all of the problems presented in the book. We are especially pleased to thank V.K. Chapman and K.M Whalen for their care and efforts in working out the solutions to these problems in detail. We also thank Sharon Chiang for providing us with her drafting skills. M. B. Boisen, Jr. and G. V. Gibbs Blacksburg, VA 2/28/90
to o u r w i v e s H E L E N and
NANCY
whose patience a n d s u p p o r t is s i n c e r e l y appreciated
MATHEMATICAL
CRYSTALLOGRAPHY PREFACE
This book is written with two goals in mind.
The first is to derive
the 32 crystallographic point groups, the 14 Bravais lattice types and the 230 crystallographic space group types.
The second is to develop the
mathematical tools necessary for these derivations in such a manner as to lay the mathematical foundation needed to solve numerous basic problems in crystallography and to avoid extraneous discourses.
To
demonstrate
how these tools can be employed, a large number of examples are solved and problems are given.
The book is, by and large, self-contained.
In
particular, topics usually omitted from the traditional courses in mathematics that are essential to the study of crystallography are discussed. For
example,
the techniques needed to work in vector spaces with non-
cartesian bases are developed.
Unlike the traditional group-theoretical
approach, isomorphism is not the essential ingredient in crystallographic classification schemes.
Because alternative classification schemes must
be used, the notions of equivalence relations and classes which are fundamental to such schemes are defined, discussed and illustrated. example, we will
For
find that the classification of the crystallographic
space groups into the traditional 230 types is defined in terms of their matrix representations.
Therefore, the derivation of these groups from
the point groups will be conducted using the 37 distinct matrix groups rather than the 32 point groups they represent. We have been greatly influenced by two beautiful books. Weyl's book entitled Symmetry
Hermann
based on his lectures at Princeton Uni-
versity gives a wonderful development of the point groups as well as an elegant
exposition
Zachariasen's
book
of
symmetry
entitled
in
art
Theory
of
and nature. X~ray
Fredrik W. H.
Diffraction
in
Crystals
presents important insights on the derivation of the Bravais lattice types and the crystallographic space groups. These two books provided the basis for many of the ideas developed in this book. The
theorems,
examples,
definitions
and corollaries are labelled
sequentially as a group whereas the problems are labelled separately as a group as are the equations. self-explanatory.
The manner in which these are labelled is
For example, T4.15 refers to Theorem (T) 15 in Chapter
4 while DA1.1 refers to Definition (D) 1 in Appendix (A) 1. v
We have strived to write this book so that it is self-teaching. reader is encouraged to attempt to solve the examples before
The
appealing
to the solution presented and to work all of the problems.
ACKNOWLEDGEMENTS
We wish to thank Virginia Chapman, a lady of exceptional talent and ingenuity, project.
for
her
enthusiastic
and
tireless
contribution
this
In particular, her preparation of the GML files used to produce
this book is greatly appreciated.
We thank John C. Groen for his dedi-
cation and his meticulous preparation of the many illustrations book.
to
in this
Margie Strickler is gratefully acknowledged for her preparation
of the GML files for the appendices.
It is also a pleasure to thank Karen
L. Geisinger for painstakingly preparing the stereoscopic pair diagrams of the C-equivalent ellipsoids for the 32 crystallographic point groups G.
We thank Don Bloss and Hans Wondratschek for beneficial discussions,
Sharon Chang for important technical advice on the drafting of the figures and her assistant, Melody L. Watson, for her draftwork.
We also thank
Bryan C. Chakoumakos, Department of Geology, University of New
Mexico,
Albuquerque, New Mexico; James W. Downs, Department of Geology and Mineralogy,
Columbus, Ohio; Karen L. Geisinger, Department of Geoscience,
The Pennsylvania State University, University Park, Pennsylvania and Neil E.
Johnson,
Department
of
Geological
Sciences,
VPI&SU,
Blacksburg,
Virginia and David R. Veblen, Department of Earth and Planetary Sciences, The Johns Hopkins University, Baltimore, Maryland for their reading the earlier drafts and useful remarks.
However, they are neither
of re-
sponsible for any errors that may be present in the book nor for the point of view we have taken in this project.
Finally, we gratefully acknowledge
the Series Editor Paul H. Ribbe for his helpful comments and criticisms and the National Science Foundation Grant EAR-8218743 for partial support of this project.
vi
EXPLANATION OF SYMBOLS SYMBOL
DESCRIPTION
S
Geometric three-dimensional space.
P
A primitive lattice or the basis for a primitive lattice.
[r]p
The triple representation of r with respect to the basis
Lp *
D
*
*
*
= {a ,b ,c }
D.
The lattice generated by D . The reciprocal lattice of
D.
Mp(a)
The 3x3 matrix representation with respect to the basis D of a when a is a point isometry and of the linear component of a when o is an isometry.
M
The set of all MpCtx) where a t G .
D(C)
I
The set of all isometries.
T
The set of all translations.
D{O)
The basis {T (O),T (O),T (O)} of S where D = {t ,T ,T } is a basis fori. x ^ y ^' z x y i
j
R
(C)
The set of all R c,( 0 )(°) where a t G .
{M | t}
The Seitz notation for the 4x4 matrix representation of an isometry.
orb-y-(o)
The orbit of O under the translations of 7".
A Q (a)
The linear component of a.
Aq(C)
The set of A Q ( o ) where a e
T{G)
The set of all translations in C .
T^
The set of translations associated with the lattice L.
tr(M)
The trace of the matrix M.
det(M) = |M|
The determinant of the matrix M.
#(H)
The number elements in H .
o(a)
The order of the isometry a.
[uvw)n
An nth-turn whose axis is along ua + v b + w c where D = {a,b,c} is a given basis.
[uvw]n
m
G.
An nth-turn screw about the vector ua + v b + w c with a translation of m r / n where r is the shortest nonzero vector in the lattice in the [uvw] direction.
/'
The inversion.
Basic conventions
Points in S are denoted by lower case letters, vectors and their endpoints by bold-faced lower case letters, lengths of vectors by italics, sets by capital italics and matrices by capital letters. vii
MATHEMATICAL CRYSTALLOGRAPHY CONTENTS
Page
COPYRIGHT; LIST OF PUBLICATIONS
ii
DEDICATION
iii
FOREWORD
iv
PREFACE
v
ACKNOWLEDGMENTS
vi
EXPLANATION OF SYMBOLS
C h a p t e r 1.
vii
MODELING SYMMETRICAL PATTERNS AND OF MOLECULES A N D C R Y S T A L S
GEOMETRIES
INTRODUCTION
1
Symmetrical patterns in molecular structures Symmetrical patterns in crystals
1 3
A MATHEMATICAL DESCRIPTION OF THE GEOMETRIES OF MOLECULES AND CRYSTALS
8
Geometric three-dimensional space Vector addition and scalar multiplication Triples Space lattices Vector spaces Vector space bases The one-to-one correspondence between S and R 3 Coordinate axes LENGTHS AND ANGLES
25
Inner product Metrical matrix Cross product Triple scalar product
Chapter 2.
9 10 11 12 16 18 21 23
25 26 34 38
S O M E G E O M E T R I C A L A S P E C T S OF
CRYSTALS
INTRODUCTION
41
EQUATION OF PLANES AND LATTICE PLANES
42
Lattice planes The equation of a plane Miller indices cf-spacings
42 42 44 46 viii
RECIPROCAL BASIS VECTORS
47
Direct and reciprocal lattices D and D* compared
51 51
CHANGE OF BASIS
56
Zones
63
APPLICATIONS
65
A DESCRIPTION OF THE GEOMETRY OF A CRYSTAL IN TERMS OF A CARTESIAN BASIS
72
Calculation of angular coordinates from crystallographic data DRAWING CRYSTAL STRUCTURES C h a p t e r 3.
75 83
POINT ISOMETRIES - VEHICLES DESCRIBING SYMMETRY
FOR
INTRODUCTION
91
ISOMETRIES
91
Rotations Orientation symbols Compositions of isometries Rotoinversions
92 95 95 96
SYMMETRY ELEMENTS
99
DEFINING SYMMETRY
100
LINEAR MAPPINGS
101
Matrix representations of linear mappings Matrix representations of compositions of linear mappings Algebraic properties of 322 THE CONSTRUCTION OF A SET OF MATRICES DEFINING THE ROTATIONS OF 322
Chapter 4.
THE MONAXIAL C R Y S T A L L O G R A P H I C
105 108 117 110
POINT
GROUPS
INTRODUCTION
123
ALGEBRAIC CONCEPTS
123
Binary operations Groups Symmetry groups
123 125 127 ix
CRYSTALLOGRAPHIC RESTRICTIONS
129
MONAXIAL ROTATION GROUPS
134
Matrix representations and basis vectors Equivalent points and planes
C h a p t e r 5.
THE POLYAXIAL CRYSTALLOGRAPHIC
141 144
POINT
GROUPS
INTRODUCTION
157
PROPER POLYAXIAL POINT GROUPS
157
CONSTRUCTION OF THE DIHEDRAL GROUPS
168
CONSTRUCTION OF THE CUBIC AXIAL GROUPS
173
CONSTRUCTION OF THE IMPROPER CRYSTALLOGRAPHIC POINT GROUPS
. . . .
180
THE CRYSTAL SYSTEMS
183
SCHOENFLIES SYMBOLS
191
THE ICOSAHEDRAL POINT GROUPS
192
C h a p t e r 6.
THE BRAVAIS
LATTICE
TYPES
INTRODUCTION
199
LATTICES
199
A DERIVATION OF THE 14 BRAVAIS LATTICE TYPES
207
Lattices Lattices Lattices Lattices Lattices Lattices Lattices Lattices Lattices Lattices Lattices
invariant invariant invariant invariant invariant invariant invariant invariant invariant invariant invariant
under under under under under under under under under under under
7 2 3 4 6 222 322 U22 622 23 432
208 208 213 217 220 220 222 222 222 222 222
THE 14 BRAVAIS LATTICE TYPES
223
MATRIX GROUPS REPRESENTING THE CRYSTALLOGRAPHIC POINT GROUPS
x
...
225
Chapter 7.
THE CRYSTALLOGRAPHIC
SPACE GROUPS
INTRODUCTION
229
TRANSLATIONS
229
ISOMETRIES
237
CRYSTALLOGRAPHIC SPACE GROUPS
249
CRYSTALLOGRAPHIC SPACE GROUP OPERATIONS
258
THE CRYSTALLOGRAPHIC SPACE GROUP TYPES DERIVED FROM THE ONE-GENERATOR POINT GROUPS
262
THE CRYSTALLOGRAPHIC SPACE GROUP TYPES DERIVED FROM THE TWO-GENERATOR POINT GROUPS
276
THE CRYSTALLOGRAPHIC SPACE GROUP TYPES DERIVED FROM THE
THREE-GENERATOR POINT GROUPS
295
Appendix 1.
MAPPINGS
303
Appendix 2.
M A T R I X METHODS
309
OPERATIONS
310
SOLVING SYSTEMS OF LINEAR EQUATIONS
312
Reduced row echelon matrices
317
DETERMINANTS
326
INVERSES Appendix 3.
330 C O N S T R U C T I O N A N D I N T E R P R E T A T I O N OF M A T R I C E S REPRESENTING POINT ISOMETRIES
INTRODUCTION
339
Cartesian bases General bases
339 340
INTERPRETATION OF MATRICES REPRESENTING POINT ISOMETRIES Cartesian bases General bases
342 342 345
PROOFS OF MAIN RESULTS
352
xi
Appendix 4.
POTPOURRI
HANDEDNESS OF BASES
357
DISCUSSION AND PROOF OF T6.15
358
Appendix 5.
SOME P R O P E R T I E S OF LATTICE PLANES
361
Appendix 6.
INTERSECTION ANGLES BETWEEN ROTATION A X E S
DIHEDRAL GROUPS
371
CUBIC AXIAL GROUPS
373
Appendix 7.
EQUIVALENCE RELATIONS, COSETS AND FACTOR GROUPS
EQUIVALENCE RELATIONS
379
EQUIVALENCE CLASSES
382
COSETS
385
FACTOR GROUPS
389
Appendix 8.
ISOMORPHISMS
395
REFERENCES
399
NEW to the REVISED EDITION SOLUTIONS TO PROBLEMS
402
INDEX
456
xii
CHAPTER 1
M O D E L I N G S Y M M E T R I C A L P A T T E R N S A N D GEOMETRIES OF MOLECULES AND
CRYSTALS
"All things are made of atoms - little particles that move around in perpetual motion, attracting each other when they are a little distance apart, but repeling upon being squeezed into one anotherRichard Feynman INTRODUCTION
Symmetrical principle
Patterns
in
Molecular
Structures:
The
minimum
an arrangement wherein the total energy of the resulting is minimized. gregate,
energy
states that the atoms in an aggregate of matter strive to adopt configuration
When such a condition is realized, the atoms in the ag-
whether
large
or small in number, are characteristically
peated at regular intervals in a symmetrical pattern.
re-
In recent years,
molecular orbital methods have had great success in finding minimum total energy structures for small aggregates
(molecules), using various algo-
rithms for optimizing molecular geometry (cf. Hehre et at., references therein).
1986
and
Not only do these calculations reproduce known mo-
lecular structures within the experimental error, but they also show that when the total energy is minimized certain atoms in the molecule are repeated at regular intervals in a symmetrical pattern about a point, line or a plane.
( E 1 . 1 ) Example - Repetition of a p a t t e r n at r e g u l a r i n t e r v a l s about a point and a line:
Monosilicic acid, H^SiO»,
is a small molecule whose atoms
are repeated at regular intervals in a symmetrical pattern about a point and a line (Figure 1.1).
An optimization of the geometry of this molecule
using molecular orbital methods shows that its total energy is minimized when an OH group of the molecule is repeated at regular intervals of 90° about a point at the center of the Si atom and at regular intervals of 180° about a line to give the molecular structure displayed in Figure 1.1. The repetition of the group at regular intervals about a line is called rotational symmetry, whereas that about a point is called rotoinversion symmetry.
Rotations and rotoinversions and how they can be used to define
the symmetry of this molecule will be examined in Chapters 3 and 4.
F i g u r e 1.1 ( t o the l e f t ) : as
determined
in
near
A drawing of the molecular structure of monosilicic acid, Hj.SiOj,, Hartree-Fock molecular orbital calculations
O'Keeffe and Gibbs, 1984).
(Gibbs et al., 1981;
The intermediate-sized sphere centering the molecule represents
Si, the four largest spheres represent 0, and the smallest spheres represent H.
The sizes
of the spheres in this drawing or in any other drawing in this book are not intended to mimic the actual sizes of atoms in molecules or crystals.
F i g u r e 1.2 ( t o the r i g h t ) :
A drawing of the structure of a tricyclosiloxane molecule com-
posed of three "tetrahedral" Si(0H) 2 groups bonded together into a 6-membered ring.
The
large spheres represent 0, the intermediate-sized spheres Si, and the small ones H.
The
structure of the molecule was determined by O'Keeffe and Gibbs (1984), using molecular orbital methods.
( E 1 . 2 ) Example - Repetition of a p a t t e r n at r e g u l a r i n t e r v a l s about lines and across planes:
Tricyclosiloxane, H 6 S i 3 0 3 , is an example of a mole-
cule whose atoms are repeated at regular intervals in a symmetric pattern about
lines and across planes (Figure 1.2).
The total energy of this
molecule is minimized when a "tetrahedral" Si0 2 H 2 group is repeated at regular intervals about a line to form a planar 6-membered ring of three Si and three 0 atoms.
Imagine a line drawn perpendicular to the plane
of the ring and passing through its center.
Note that the atoms of the
molecule are repeated in a symmetrical pattern about this line at regular intervals of 120°. repeated
Also note that the hydrogen atoms of the molecule are
across the plane of the ring.
The regular repetition of the
structure across a plane is called reflection symmetry.
There are other
lines and planes in the molecule about which the atoms of the molecule are repeated, but a study of these elements will be deferred to Chapter
2
Symmetrical Patterns in C r y s t a l s :
When a large aggregate of atoms (typ-
21
ically "lO ") strives to adopt a configuration wherein the total energy is minimized, we may again find that some atomic pattern of the aggregate is similarly
repeated
across planes.
at
regular
intervals about points and lines or
But, unlike a molecule, the pattern may also be repeated
at regular intervals along straight lines to produce a periodic pattern of atoms in three dimensions. is said to be a crystal
Such a three-dimensional aggregate of atoms
or a crystalline
solid,
whereas the actual atom
arrangement of the solid is referred to as its crystal book, we shall only be concerned with ideal crystals.
structure.
which contain a variety of flaws and irregularities, envisaged as being perfect in every respect.
In this
Unlike real crystals ideal crystals are
Also the atoms in such a
solid are envisaged to repeat indefinitely at regular intervals in three dimensions.
In addition, the positions of the atoms in such a crystal
are envisaged to be static and to be specified exactly by a set of atomic coordinates.
Thus, when we make reference to a crystal or a crystalline
solid, we shall be referring to an ideal crystal. structure
at
regular
intervals
along
The repetition of a
straight
lines
is
called
translational symmetry, a subject discussed in Chapters 6 and 7. (El.3)
Example - Repetition of a pattern at regular
straight line:
intervals
along
a
As stated above, a characteristic feature of a crystalline
solid is that some atomic pattern in a large aggregate of atoms is repeated at regular intervals along straight lines.
Consider the string
of silicate tetrahedra in Figure 1.3 isolated from the crystal structure of
a-quartz, a common mineral of Si02 composition comprising about 12
percent of the continental crust.
Fix your attention on any two adjacent
tetrahedra in the string and imagine that this pair of tetrahedra is repeated at regular intervals indefinitely in the direction of the string. Whenever some atomic pattern in a crystal (like the pair of tetrahedra in the string) is repeated along some line at regular intervals, it is convenient to represent such a periodic pattern by a directed line segment (a vector) parallel to the string and whose length equals the repeat unit of the pattern.
Such a vector (labelled a in this case), drawn next to
the string of tetrahedra in Figure 1.3, is called a translation vector. (El.4)
Example - The c r y s t a l s t r u c t u r e of a-quartz:
a-quartz crystal structure is presented in Figure 1.4.
3
A drawing of the As observed for
Figure 1.3: A string of silicate tetrahedra isolated from the crystal structure of aquartz. Each silicon atom (small sphere) in the string is bonded to four oxygen atoms (large spheres) disposed at the corners of a SiCU silicate tetrahedron. The lines connecting the atoms in the string represent the bonds between Si and 0. Direct your attention on any two adjacent tetrahedra in the string and note that this pair of tetrahedra is repeated at regular intervals so that the repeat unit is given, for example, by the distance between Si atoms in alternate silicate tetrahedra. The repeat along the string is represented by a parallel vector a whose magnitude» cr, equals the repeat unit along the string. The ellipses, (...), at both ends of the string indicates that this sequence of silicate tetrahedra repeats indefinitely in the direction of the string, even though the sequence is terminated in the figure.
? •CTi J—O
cS
w? W W
w?
Figure 1.4: The crystal structure of a-quartz projected down a direction in the crystal along which the pattern of atoms displayed in the drawing is repeated. The SiOfc groups in the structure share corners and form spirals of tetrahedra that advance toward the reader and that are linked laterally to form a continuous framework of corner silicate tetrahedra. The vector a represents the repeat unit of the structure in the direction of a; b represents the repeat unit in the direction of b.
4
F i g u r e 1.5: A view of the a - q u a r t z structure tilted about 2° off the viewing d i r e c t i o n in Figure 1 . 4 . The repeat unit along the viewing d i r e c t i o n is represented by the vector c w h o s e m a g n i t u d e equals the separation b e t w e e n equivalent atoms in the lines of atoms paralleling c. Because crystals consist o f periodic three-dimensional patterns of atoms disp o s e d along w e l l - d e f i n e d lines, w h e n e v e r a crystal like a - q u a r t z is v i e w e d along one of these d i r e c t i o n s , the arrangement w i l l b e simplified by the fact that only the atoms in the repeating u n i t will b e seen as in F i g u r e 1 . 4 . Also, the shorter the repeat u n i t along such a v i e w i n g d i r e c t i o n , t h e simplier the arrangement because the repeat unit must involve fewer atoms. W h e n the crystal is t i l t e d off this direction, t h e n the view becomes m u c h more c o m p l i c a t e d w i t h the u n c o v e r i n g of the m a n y atoms that lie b e n e a t h the atoms in the repeating unit. A l t h o u g h the repeat p a t t e r n of the structure d i s p l a y e d in Figure 1 . 4 and 1 . 5 is finite, the p a t t e r n is assumed to continue uninterrupted in the d i r e c t i o n of a , b a n d c indefinitely in a ideal crystal.
monosilicic acid, each Si atom in the structure is bonded to four nearest neighbor 0 atoms disposed at the corners of a tetrahedron.
In addition,
as each 0 atom is bonded to two nearest neighbor Si atoms, the structure can
be
viewed
as
a
framework
structure
of
corner
sharing
silicate
tetrahedra.
As the structure in Figure 1.4 is viewed down one of the lines along which an atomic pattern
is
repeated, the atoms along this line are one
on top of the other so that only the atoms in one repeat unit along the line
are visible.
Thus beneath each Si atom displayed in the
figure,
there exists a line of Si atoms equally spaced at regular intervals that extends indefinitely.
Likewise beneath each oxygen atom in the
figure,
there exists a comparable line of oxygen atoms also equally spaced at the same
regular
intervals.
However, when the structure
in Figure
1.4 is
tilted off the viewing direction by about 2°, the repeating pattern of atoms along this direction is exposed as in Figure 1.5.
5
By convention,
the repeat unit along each of these lines is represented by a parallel vector c whose length, c, is equal to the separation
(the repeat unit)
between adjacent atoms in the lines of equivalent Si atoms and 0 atoms that parallel the viewing direction. Returning to Figure 1.4, note that the tetrahedra running across the figure in strings from left to right are exact replicas of the ones comprising the string in Figure 1.3.
In fact, several such parallel strings
are displayed in the figure running left to right. another
such
set
of
strings
of
tetrahedra
In addition, note that
runs
across
the
figure
diagonally from the lower right to the upper left and another runs from the lower left to the upper right, both intersecting the first set strings at exactly 120°.
of
As shown in Figure 1.4, the unit repeat along
the left-to-right trending set of strings is represented by the translation vector a ,
whereas that along the diagonal set of strings running
from the lower right to the upper left is represented by the translation vector b.
In addition to defining the
repeat
unit
along
strings
of
tetrahedra, the pattern at both ends of these vectors is exactly the same regardless of their location in the structure provided the vectors have not been rotated from their original orientations.
This property can be
illustrated by laying a sheet of tracing paper on Figure 1.4, tracing a and
b
on
it and then sliding
(translating) the sheet over the figure
making sure that the vectors on the sheet are kept parallel with those on the drawing.
Note that the pattern at the end points of both a and
b is an exact copy of that at their origin regardless of the placement of the vectors on the drawing, provided that the vectors on the sheet are kept parallel with those on the figure. The lengths
(magnitudes) a, b and c of the translation vectors D =
{a,b,c} and the interaxial angles between them denoted a =
CN
( c )
D
"-1
-1
1
1
0
0
1
0
t
"l" (b)
D
=
0
o' 1
»
0
D
=
-1 0
20
0
>
0
1
"-21
1 ( d )
"0
y
2 0
0' >
0 1
T h e one-to-one correspondence between S a n d R3:
Let D = {a,b,c} de-
note a basis for S and let W denote any vector in S.
Then
Wi w2
[W],
w
where
the
unique
representation
of
vectors of D is W = W j a + w 2 b + w 3 C . R
as a linear combination of the
Hence corresponding to each vector
there is a unique triple [ W ] ^ in R3.
in S, 3
w
>.
Conversely, each vector in
is the triple of some linear combination of D and hence gives rise
to a unique vector in S.
Consequently, we have the one-to-one
corre-
spondence between S and R3 given by
w
[w].
or written another way: Wi
Wia + w 2 b + WjC
w2 w3
This one-to-one correspondence is the fundamental reason why R3 can be used to model three-dimensional geometric space S. We have already seen that S and R3 are both three-dimensional vector spaces.
As such, each has a vector addition and scalar product defined
on it.
One important property of the W
it
"preserves"
these
vector
space
< +
-
[ w ] ^ correspondence is that
operations.
V £ S, then u + v corresponds to [u]^ + [v]^.
For
example,
if
U,
Hence, to add two vectors
in S we first find their corresponding triples, add the triples and then convert
that sum into its corresponding vector in S.
This eliminates
the necessity of using the clumsy parallelogram rule for adding geometric vectors. x[u]Q.
Similarly,
if
U z S
and
x e R,
then
xu
corresponds
to
To formalize and justify these remarks we have the following
theorem. (T1.9) T h e o r e m :
Let D = {a,b,c> denote a basis of S.
lowing two statements are true:
21
Then the fol-
[u + V]Q = [U] D + [v]Q
(1) (2)
Proof: u,,
t
x u
]/)
=
f o r
Let u, V e S.
U2,
U3,
VL
V2
V,a + v 2 b + V 3 C.
a 1 1
for all u, v x
z
R
and
u
e
e
S;
S.
Since D is a basis of S, there exist real numbers and
v3
such
that
U = u ^A + u2 b + u, c and V =
Hence
u + v = (ui a + u2b + u3c) + (x^a + y2b + v3c) +
= In R
3
+ (u2 + v2)b + (u2 + v3)c .
(1.6
we have
[u]D =
U1
VI
u2
Vi
and
[u]D + lv]D =
Ui u2 U
"3.
But according to equation (1.6), this
last triple
+ Vi +
3 + V3
is also
[U + V]^.
Hence [u + v ] ^ = [u] D + [v]^.
(PI.7) Problem:
•
Prove part (2) of T1.9.
(PI.8) Problem - Calculating vectors in the lattice of a-quartz: In El.5 we found the triple corresponding to several vectors labeled in Figure 1.14.
Estimate r + U using the parallelogram rule and then determine
[r +
from the figure.
and compare your answers.
Now calculate [r + U]^ using Theorem
T1.9
Use the theorem to calculate each of the fol-
lowing: (a)
[-r] D
(b)
[6r + 2u]0
(c)
[3r - 5 u ] d .
Theorem T1.9 shows that, as vector spaces, S and
are identical.
The mathematical statement of this fact is that S and R 3
are isomorphic
and that the mapping of S to R ! that takes w to [wj^ is an isomorphism. If we choose an origin
0
and a basis
D = {a,b,c}
in
S,
then as ob-
served earlier the vectors 0, a, b and C are fundamental to establishing a frame of reference on S.
To find the triples that correspond to these
vectors,
0 =
we
observe
that
0a + Ob + 0c,
0a + lb + 0c and c = 0a + Ob + lc.
Hence
22
a =
la + Ob + 0c,
b =
[0 ]
D
[a].
=
1
[c]D
D
=
In particular, the basis of R 3 that corresponds to D is
"l 0 0
"0 »
1 0
0 y
0
(1.7)
_1
Consequently, no matter how peculiar the geometric relationship between a, b and c may be, the corresponding triples in R 3 are very simple. This simplicity is a great help in conveniently describing features in S with respect to the established frame of reference.
For example, the
set of all vectors in the space lattice defined by D is represented in R3
as the set Z 3 of all triples with integer entries.
However, caution
must be exercised when lengths of vectors and angles between vectors are considered since, for example, in spite of the great similarity of the three vectors in (1.7), their corresponding vectors a, b and C may vary greatly in length.
We shall discuss how to overcome this problem later
in the chapter. Vectors in S that lie in the direction of a can be written in the simple form xa for some x z R. written
in the
form y b
Similarly, vectors along b and C can be
and ZC, respectively, where y , z E R.
Since
D = {a,b,c} forms a basis, any vector V E S can be written as a linear combination V = xa + y b + ZC.
Hence, geometrically v can be
pictured
as the sum of three vectors each in the direction of a basis vector (see As the correspondence between S and R3
Figure 1.15(a)).
can decompose a vector in R3
[xa]
D
in a similar manner.
[yb]D =
suggests, we
Since
[ZC].
and since these are scalar multiples of the basis vectors in (1.7), we have the correspondence pictured in Figure 1.15(b). Coordinate A x e s :
Let D = {a,b,c} denote a basis for S.
As in the case
of a-quartz, a, b and c will usually be chosen so that each lies in an 23
Z=
\rsc\r,eR\
v = >-a+/b+zc
\rt€f\
Figure 1.15.
A graphical representation of the basis vectors and coordinate axes in (a)
geometric space 5 and (b) R1 .
In (a), basis vectors a, b and C are directed along coor-
dinate axes X, Y and Z, respectively. are displayed with [ a ] [ b ] p there
exists
xa + yb + zc.
three
real
In (b), the triple representatives of these vectors
and [c]^ placed along X, Y and Z.
numbers
X,
y
and
z
such
that
V
For each point V t S, can
be written
as
V =
Likewise, for each vector V t S, there exists a triple representative of
v, [v]^ E R3 such that [v] D = x[a\D The
purpose of this
V E 5 and [V]^ t R1.
figure
is to show
+ y[b)D
+ z[c]D
the correspondence that exists between vectors
No geometrical significance should be attached to Figure
other than as a model for Figure 1.15(a).
1.15(b)
The vectors in 5 have length and direction and
an angle can be defined between any two nonzero vectors in S.
On the other hand, as R J
is just a set of triples, there is no intrinsic meaning to the notions of the length of a vector or the angles between vectors in RJ.
24
important direction relative to the structure of the crystal under study. Since these directions will be important to us, we call the set of all points
lying
along them coordinate axes.
For example, the X-axis is
defined to be the set of points lying on a line passing through 0 including a. and
is
shown
| r2
{r 2 b
and
That is, the X-axis is the set of vectors {rja | Ti s in
E R)
Figure
1.15(a).
The
V-axis
is
defined
to
and the Z-axis is defined to be {r 3 c | r 3 E /?}.
X-axis consists of the vectors r = r ^
+ r 2 b + r 3 c where r2
the triples for the points on the X-axis in R
3
R) be
As the
= r3
=
0,
are (see Figure 1.15(b)):
ri X =
{
0
I r1
e
R)
0 Similarly, the triples for the points on the Y-
V =
respectively.
{
I r2
e R]
and
Z =
{
and Z-axes in R3
I r3
e
are
R)
By convention, the interaxial angles between these coor-
dinate axes are denoted a = b")b + ((a")'* c )c
53
.
(2.16)
Since ( D )
is the reciprocal basis with respect to D
, equations
of
(2.10) yield a"' (a")" = 1 and b"* (a")" = c"* (a")" = 0
Since the inner product is commutative, (2.16) becomes (a )
= a.
Sim-
ilarly (b")" = b and (c")" = c. Hence (D")" = {a,b,c}.
In
o
view of T2.6 and the definition of a reciprocal basis we have
shown that a = (b x c")/ [a"'» (b"x c*)] b = (c*x a")/[a** (b"x c"")] c = (a"x b' )/ [ a ( b " x
Let H denote the metrical matrix for D
H[r]D*
for all r s S.
=
But by T2.6, (O")" = D.
H[r]c*
for all r z S. is
[r]
=
Hence
( D
By (2.15),
y
Hence
[r] D
Also, by (2.15), G [ r ] D =
the metrical matrix for D .
.
c")]
[r] D * for all r E S where G
[r]^ = G "^[r]^* (see Appendix 2
for a discussion on the inverse of a matrix and why, since det(G) i 0, G
1
exists).
Therefore, H[r]^- = G
equality holds for all r E S, H = G
1
.
for all r e S.
Since the
Hence we have proved the following
result.
(C2.7) Corollary:
If G is the metrical matrix for D,
then G
1
is the
metrical matrix for D .
The fact that the metrical matrix of D
is the "reciprocal" of the
metrical matrix of D is consistent with calling D of D. of D
The metrical matrix of D
is denoted G .
the reciprocal basis The complete geometry
is described in terms of that of D in the following theorem.
54
(T2.8)
Theorem:
Let D = {a,b,c} denote a basis
{a ,b ,C } denote its reciprocal basis. written in terms of that of D
of
S
and let
Then the geometry of D
D
=
can be
in the following way:
a
=
(fec/y)sina
;
b
=
(ac/v)sin|3
;
c
=
(ab/v)sin!f
;
cosa
=
(cosgcosi - cosa)/sinPsini
cos (5
=
(cosacos? - cosf3)/sinasini
cosJf
=
(cosacosfJ - cosi)/sinasin3
where y = a • (b X c) .
Proof:
Since
||b x c | = facsina and
a • (b x c) =
v
(see
(1.15)
and
(1-17)), a
= (||b x c||)/(a • (b x c)) =
The expressions for b cosa , we
shall
(foc/v)sina
and c can be similarly established.
use the fact that b
• c
= b c cosa
To calculate
and the vector
identity (White, 1960, p. 76) x • z
x • w
y
y • w
(2.17)
(x x y ) • (2 x w ) = • z
Hence cosa" = (b" •
C")/(b"c") =
( v 2 b " • c")/( o 2 t>csingsini)
(2.18)
But b" • c"
=
(1/v 2 ) (c x a) • (a x b )
=
(1/v 2 )
c • a a • a =
(a 2 bc/v2)(cos&cosi
c • b a • b
occosp =
Q/V2)
- cosa)
2
a
cbcosa
abcosZ (2.19)
Substituting (2.19) into (2.18) we obtain
cosa
= (cosfScos? - cosa)/sin(5siny .
The other parts of the theorem are proved in a perfectly similar manner.•
55
Because of the * duality between D and D
*
discussed in T2.6, any ex-
= (cosScosi - cosoO/sinPsini can be used to write the
pression like cosa equality cosa
=
(cosfi* cosi * — cosa *)/sin3 * sini *
cosfS
=
(cosa* cosi * — cosP * )/sina * sini *
cosï
=
(cosa* cosft* — cosï * )/sina * sinp *
Similarly, and
CHANGE OF BASIS We learned in Chapter 1 that there are innumerable directions in a crystal along which a representative pattern of the structure is repeated at regular intervals.
Furthermore, not only do these directions define
a
system along which three non-coplanar coordinate
natural
coordinate
axes can be placed, but the repeat unit along each of these directions defines a natural set of basis vectors D = {a,b,c}.
Thus, for a given
crystal, innumerable sets of axes, basis vectors and planes can be chosen, depending on the problem to be studied.
In addition, as there are innu-
merable ways of describing such a crystal, it is essential to be able to change its geometric framework with respect to the observations made.
Moreover,
being
if we wish to study crystal structure relationships
(Smith, 1982), polymorphism, phase transformations
(Hazen and Finger,
1982) or defects (Lasaga and Kirkpatrick, 1981), it is imperative that these features be related to a single set of basis vectors.
In partic-
ular, if data are provided by one investigator describing some feature of a crystal with respect to one basis and if another investigator provides a similar set of data on another such crystal but defined with respect to a second basis, it is important to express both data sets with respect to a common basis in order to make comparisons and to draw conclusions.
In other words, we must be able to make a change of basis.
In the last section we saw how, given a basis D = {a,b,c} and its reciprocal
basis D
*
*
*
*
= {a ,b ,C }, we can easily translate geometrical *
information given in terms of D into the language of D .
For example,
if r t S and if we know [i*]^ then we can find [r]^* by, see (2.15), G[r] 0 = [r] D *
56
,
where G is the metrical matrix of D.
In this section, we will see how
to translate geometrical information from a basis D j = { a ^ b ^ C ] }
to a
- {a2,b2,c2}.
basis D2
Just as in the special case when be found that will convert
[r]n
= D and D2
into [ r ] n
basis D2
, a matrix will
for all r E S and this matrix
will be used to calculate the metrical matrix of D2 (D2.9) Definition:
- D
from that of
D^.
The change of basis matrix from the basis D i to the
is the matrix T such that
T [ r ] D i = [r] for all r
t
D ,
S.
Since we know what job T is supposed to perform, we can find T by observing that
112
' 11
t23
0
,'il
t,2
f
0_
M l
112
tl3
"o"
*2 1
t2 2
t2 3
1 0
3 3.
.'¡1
tl2
* 3 3.
'll
til
tl3
"o"
'2 1
t2 2
Î23
0
.'3 1
t 32
=
= 1st
column
'til' =
t21
\
T
of
1st
column
of T
=
2nd
column
of T
=
3rd
column
of T
>12 t
=
2 2
(2.
Î32.
tl3 =
Î23
.
.tu.
t [010] t , and [ C l ] D i = [001]
=
bi
[bi]0l
=
.tn.
1
[100]
T [ a 1 ] 0 i = [a 1 ] £ ? 2 , u
~1
1
Di
[ai]n
tl3
t22
=
T,
[bl]
[b^p. u
2
and
D2
T[Cll
D1=
[Ci]
u
basis,
exists
rlt
r2,
have
= 2nd column of T and [Cj],,
Now let r denote an arbitrary vector in S .
there
we
2
column of T.
r, E R
By T1.9, we have [r]^ = r j a j ^
D2
such that r = r ^
+ ^[bj^
57
+ ^[c^^.
= 3rd 2
Since D i
is a
+ r 2 b j + r3Cj. But then
T[r]Di=
T(r1[a1]0i + M b , ] ^
+
c , ^ ^
=
r 1 T [ a 1 ] D i + r 2 T [ b , ] D i + r,T[c,]0i
=
r1[*i]Di + r2[b,]Di + r3[Cl]D2
=
[r^i J
+ r2b! + r,Ci]n D,
•
Therefore, the fact that T "works" for [a,]- , [ b ^ n U
that it "works" for all [ r ] n , r e S.
L>1
x
and [ c ^ , ,
L>1
implies
Consequently, w e have established
the following theorem.
(T2.10) T h e o r e m :
D2
= {a2,b2,c2>
The change of basis matrix T from
= {a^b^Cx}
to
is
T =
t a i] r>
If T is the change of basis
[biln
matrix
from
f c i]/
Di
to
D2,
then
it
is
straightforward to show that T ^ exists (since the columns of T are linearly T[r] nu
independent). 1
= [r]_. u
i
by T
Furthermore,
-1
by
multiplying
both
sides
of
, we have
Therefore, T ^ is the change of basis matrix from D2 T2.10 w i t h the roles of D , and D2
to
Applying
switched, we have the following cor-
ollary.
(C2.11) Corollary:
If T is the change of basis matrix from D^
then T * is the change of basis matrix from D2
T_1
=
[a«]Di
58
[bi Id,
to D ] and
^ D ,
to
D2,
As we shall see in a later section on applications, it is often easy to find by inspection the change of basis matrix from Dz
to
in one direction, say
The change of basis matrix in the other direction is then
found by inverting the first matrix. Now that w e have a procedure for finding the change of basis matrix from Di of D2
to D2,
we need to discover how to find the metrical matrix
from the metrical matrix Gj of D x .
expression
for
T
D* = {at,b*,c*>.
using
the
reciprocal
G2
W e begin by obtaining a useful bases
= {a^b^Ci)
and
By T2.5,
b, [aj
0,
ai • b 2 .
bi
[b x ]D
2
*
•
b* ,
Ci • bi
[Ci
bi • Cj
Hence, J.
a
l
•
a2
bi
•
a
l
•
b2
b,
•
•
*
bx
c'i
•
*
bi *
Ci
Ci
•
Ci
•
"ft 32 *
b2
• C
Ci
*
2.
We now have the following equations:
^
^
=
^ d ,
G2[r]D2
=
[r]D*
Gltr]Di
= [r]D*
. -Ij.
Defining S to b e the change of basis matrix from Di
^L
to DZi
w e also have
These relationships are summarized in the following circuit diagram:
59
(2.
-
[••ID,
i
Gi
^D*
flo,
s
*
G
*
tr]
D*
>
According to this diagram,
S G x T ' V ] ^ = GAr]Di for all r E S. S.
By T2.6, D2
Hence, SGjT
-1
= G2 .
Consequently we need to calculate
is the reciprocal basis of D2 • Hence,
^D*
ai "V a.
=
(a 'zy
ai
a2
(b*)*
a'i
b2
(4)*
a'i
C2
Applying this observation to each of the columns of the change of basis matrix from D j to D 2 written in the form of (2.21), we obtain -v ai S =
a'i ai
•
•Jbx • a 2
a2
•
*
b2
•
bi
C
2
•
*
•
a
•
b
Ci
•
c
C2
•
bx
C2
•
.*
c'i
c
•
C
b2
bi
•
c2
b2
•
ai
b2
•
b2
•
Ci *
c'i *
Consider, *
•
t s =
a2
•
a2
•
a
2
ai
.* *
•
Ci
*
. *
2
bi *
l.
According to the analogous statement to (2.21), S*" is the change of basis matrix from D 2 to D x . (T
= (T^) \
That is, S 1 = T _ 1 .
we write T ^.
(T2.12) Theorem:
Since
Hence we have the following theorem.
Let D j and D2
matrix from D j to D2
Therefore, S = (T _1 ) t .
denote bases, T the change of basis
and let G x denote the metrical matrix for D x . 60
Then
the relationship between Gj and G 2 , the metrical matrix for D2,
is given
by Gi = T^G-J
Gj = T ' ^ h T " 1
and
.
We summarize these results in the following circuit diagram. T [r] T^GiT = Gj
[r]
I T
^DÏ (T2.13) Theorem: G.
Then the volume
^D*
Let D = {a,b,c} denote a basis with metrical matrix v of the parallelpiped outlined by D is such that
v 2 = det(G)
Proof:
(2.22)
G i = T" t G 1 T" 1
I _t
.
Let C denote a cartesian basis and let T denote the change of
basis matrix from C to D.
By (1.18) we know that v = det(M) where
M =
[a] r
I
[b],
Note that TM
Hence det(TM) = 1.
[T[a]c
=
=
[[a] D
=
I3
I T[b]c I [b]D
I T[c] c ]
I [c] D ]
•
Therefore,
1
= det(TM) = det(T)det(M) = det(T)v
Consequently, det(T) = 1/v.
Since the metrical matrix for C is I 3 ) by
T2.12, 13
(by (A2.8))
.
= T^T
61
.
Since det(T ) = det(T), 1
= det(T)det(G)det(T) = (l/v2)det(G)
.
v2
Therefore, det(G) =
We are now in a position to show how the cross product is calculated when the vectors are expressed with respect to an In
Chapter
arbitrary
basis
D.
1, we discussed how to calculate v x w with respect to a
cartesian basis. (T2.14) Theorem:
Let D = {a,b,c} denote a basis with metrical matrix
G and let r and S denote vectors in S.
Then a
det(G) -i
r x s
b
G[r]
c Proof:
D
(2.23)
G[S]
D
Let rj, r 2 , r 3 , Sj, s 2 and s 3 E R be such that JU
X
JL
r
=
rja
+ r2b
+ r3c
,
s
=
Sia
+ s2b
+ s3c
,
and
J-
where D
rV
= {a ,b ,C } is the reciprocal basis for D. r x s = =
(ria" + r 2 b" + r 3 c") x (ija" + 5 2 b" + s3c") Cr253 - r 3 s 2 )(b" x c") + ( r 3 s 1 - r^j)c" x a" + (r^j - s ^ ) a
where we have used Chapter 1.
Then
the properties
x b
,
of the cross product discussed in
By T2.6,
r x 5 = v"[(r 2 s 3 - r 3 5 2 )a + (r3Si - ri5 3 )b + (rjS2 - 5^2)0] where v
= a
• (b" X C ).
Hence,
62
,
r x s = v
By T2.13, (v")2 = det(G").
a
ri
Si
b
r2
s2
c
r3
s3
By C2.7, G" = G _ 1 and so =
(detCG*))*
=
(detCG"1))^ (det(G))"i
thus the theorem is established. Let D = {a,b,c} denote a basis with metrical matrix G.
V 2 = det(G) =
a2
abcosTS
abcosi
b2
becosa
accosg
bccosa
c2
By T2.13,
accosfl
and so we find that V =
obc(1
(P2.8) Problem:
- cos2a - cos2f5 - cos2Y + 2cosacosf5cosi)^ Show that (v")2 =
the parallelepiped outlined D V
= a b c (1 - cos a
det(G") where v" is the volume of
= {a ,b ,C } and that
— cos &
— cos i
+ 2cosa cosfS cosi• M )
-1 * By C2.7, G is the metrical matrix for D . This reciprocal relationship between the metrical matrices of D and D yields the reciprocal volume relationship V2 = det(G) = l/det(G_1) =
1/v*2
and therefore v = 1/v . Zones: indices
Suppose the nonparallel lattice planes P^ and P2 k^ 2.x) and (h2
k2
have Miller
H2). respectively, then the zone axis de-
fined by them is in the direction of a vector parallel to the intersection 63
of Pi and P 2 .
Hence if
si
=
h^a
+ /Cib
+ £iC
s2
=
h2a
+ Ar2b" + Z2c"
,
and ,
then the zone axis is in the direction of SI X S 2 . (E2.15)
Example
lattice v e c t o r s :
-
The
vector p r o d u c t of two non-collinear reciprocal i Show that det(G) 2 (S! X s 2 ) is in the direct lattice L p
where G is the metrical matrix for D. Solution:
By T2.14, a 2
det(G) (S! X S 2 )
b
=
G[ S l
'D
G[S2
'D
c a
hi
h2
b
ki
k2
c
n2
Hence det(G) ? (S! X s 2 ) = ua + vb + W C where
Hi
Since hi, k i y llt
k2
h2
hi
h2
«2
ii
ki
k2
h2,
k2
and l2 are all integers, so are u, v and w .
Hence det(G)^(S! X S 2 ) c L P .
c
The U, v and w in this example define the zone axis.
To distinguish
such a set of integers from a set defining a crystal plane (/?/(£), the integers for the zone are enclosed between a pair of brackets [t/vw] . (E2.16) by
two
Example - F i n d i n g non-collinear
a vector p e r p e n d i c u l a r to the plane
vectors
in
a
crystal:
The
lunar
defined mineral
pyroxferroite (Fe,Ca)Si03 is triclinic with cell dimensions a = 6.621A,
64
b = 7.551A, c = 17.381A, 1971).
a = 114.27°,
3 = 82.68°,
X = 94.58°
(Burnham,
Calculate the cross product of the following two vectors r3„
= -0.0963a + 0.1243b + 0.2018c
rs„
=
0.1084a - 0.0880b + 0.2947c
to find a vector perpendicular to their plane. Solution:
Calculating G with the cell dimension of pyroxferroite, we find 43.8376 G =
and (detG)2 = 7 8 5 . 3 4 6 6 .
r3„ x r 5 4
=
-3.9922
14.6624
-3.9922
57.0176
-53.9461
14.6624
-53.9461
302.0992
Hence,
(785.3466)
-1
a
-1.7589
9.4243
b
-3.4146
-21.3482
c
52.8461
95.3653
= 1.0219a + 0.8478b + 0.0888c is a vector perpendicular to the plane of r 3 1 ( and r 5 1 i . (P2.9)
Problem:
Calculate the cross product
k x i
for pyroxferroite
given that k
=
0.1166a + 0.0968b + 0.0101c
i
= -0.0286a + 0.0369b + 0.0599c
and .
APPLICATIONS
In the previous section, we introduced a method for finding the entries of a transformation matrix T.
In practice, however, the entries
of such a matrix may be found by making a careful drawing of a crystal structure or its lattice representation that shows how one set of basis vectors is related to another set.
Then by examining how the vectors of
one basis can be expressed as a linear combination of the other, the coefficients of the second basis vectors are used as columns in the ma-
65
X,
Figure
2.4:
A drawing of the oxygen atoms (stippled spheres) in the
kyanite structure idealized so that they are close-packed at the corners
19
of a cubic face-centered array (modified after Taylor and Jackson, 1928). The Di = ( a ^ b x , ^ ) basis vectors directed along Y i,
Z i,
outline
(a 2 > b 2 ,Ci) directed
a
unit
cell
of
along Xlt
the
kyanite
coordinate
axes
structure
and
outlines a cell of the
Xlt O2 = cubic
face-centered array of oxygen atoms.
trix.
This method will be illustrated with an example.
Another method
for finding T is illustrated in EA2.23. (E2.17) Example - Determination of the cell dimensions of a subcell of the kyanite structure:
The oxygen atoms comprising the structure of kyanite,
Al 2 Si0 5 , can be viewed as a slightly distorted cubic close-packed facecentered structure with Si occupying 10% of the available tetrahedral voids and A1 occupying 40% of the available octahedral voids (Taylor and Jackson, 1928).
Before the structure of this mineral was solved, the
close-packed nature of the structure was theorized because the dimensions of
the
unit
cell
of
kyanite
outlined
by
the
natural
basis
Di =
{aijb^Ci} are similar to those calculated from a set of basis vectors Di
=
i a 2>b2C2) defining a face-centered subcell of oxygen atoms. The relationship between the D2 -basis of the subcell and the
basis of the kyanite cell is displayed in Figure 2.4.
Dx-
Inspection of this
figure shows that the D^basis vectors can be written in terms of the D2-basis vectors as follows: ax
= 3/2a2 - l/2b2 + c 2
bx
= 2b 2
Cj
= - a 2 + c2
Cfi
.
A recent measurement of the cell dimensions of kyanite at 25°C
(Winter
and Ghose, 1979) yielded the values a x = 7.126A, b ! = 7.852A, c x = 5.572A, Oi = 89.99°, 3! = 101.11° and
= 106.03° for D1.
W i t h this information,
calculate the cell dimensions of the subcell defined by the oxygen atoms in kyanite.
Using T2.10, we can construct the change of basis matrix
Solution:
[ai]
3/2
0
-1
-1/2
2
0
1 0
from Dx
to
1
D2
Using the cell dimensions for D j , its metrical matrix Gj is
Gx
=
50.7799
-15.4510
-7.6511
-15.4510
61.6539
0.0076
-7.6511
0.0076
31.0472
To compute the cell dimensions of the face-centered cell, we need to solve for the metrical matrix G 2 of D 2 .
According to T2.12,
G2 = T"tG1T"1
Inverting T (see Appendix 2),
3/2 T"
1
=
-1/2 1
.
(2.
we find that
0
-1
2
0
0
1
-1 =
' 2/5
0
2/5
1/10
1/2
1/10
-2/5
0
3/5
Substituting T " t , Gj and t " 1 into (2.24) we have
67
2/5 0
2/5
1/10
-2/5
50.7799
-15.4510
-7.6511
0
-15.4510
61.6539
0.0076
3/5
-7.6511
0.0076
31.0472
1/2
1/10
2/5
0
2/5
1/10 1/2 -2/5
1/10
0
3/5
14.9205
-0.0090
-0.5580
a2
a2b2cosZ2
a2c2cosfl2
-0.0090
15.4135
-0.0052
o 2 b 2 cosi 2
2 b2
b2c2coscc2
-0.5580
-0.0052
15.0106
a 2 c 2 cosP 2
b 2 c 2 cosa 2
2 c2
Equating the entries of these two matrices and solving for the cell dimensions of the face-centered subcell, we find that a2 = 3.8627A, b2 = 3.9260A, c 2 = 3.8743A, o 2 = 90.02°, & 2 = 92.14° and Z2 = 90.03°.
As is
evident from these results, the departure of the oxygen atoms in kyanite from
an
ideal
cubic
close
packed
subcell
with
o 2 = b2 = c2
and
o 2 = P 2 = y 2 = 90° is small. (P2.10)
o
Problem: The crystal structure of the relatively rare mineral
sapphirine, (AlMg)h(Al2Si)202„, can also be described as a slightly distorted cubic close-packed array of oxygen atoms
(Moore,
1968).
The
equations that define the basis vectors of the sapphirine structure Dx = {a 1 ,b 1 I c 1 } in terms of the face-centered subcell D2 = {a 2 ,b 2 ,c 2 } are aj = 2a2 + 2b 2 bj = -5/2a2 + 5/2b z c x = -a 2 - b 2 + 2c2 (1)
Using
the
cell
Ci = 9.957A,
dimensions
.
o, = 11.286A,
bx = 14.438A,
= 125.4°, and o, = Ti = 90.0°, measured for the
mineral (Higgins and Ribbe, 1979), show that the metrical matrix defining the geometry of the face-centered subcell is
G2 =
(2)
16.2991
-0.3774
-0.1762
-0.3774
16.2991
-0.1762
-0.1762
-0.1762
16.4722
(2.25)
Evaluate the entries of (2.25) and show that the cell dimensions of
the
subcell
are
a2 = b2 = 4.037A,
o 2 = P 2 = 90.62 and Z2 = 91.33. 68
C2 = 4.059,
(E2.18) Example - Transforming indices of planes with change of basis: The close-packed monolayers of the kyanite structure parallel (111), (111) and (111) of its face-centered subcell.
(111),
Determine the
indices of these planes in terms of the kyanite basis. Solution:
We recall that perpendicular to each stack of planes
{h2k1l1)
there exists a vector S with the coordinates such that
D,
=
To find the coordinates of this vector in terms of the
basis, we use
the equation (see (2.22)) =
^ D *
'
(2
"
where the components of [ s ] n * are the indices of the same plane but defined in terms of the kyanite basis.
Transposing T and substituting
this result into (2.26), we obtain "3/2 -1/2
hi ki
=
Replacing (h2k2l2} we get
(220),
1
h2
0
2
0
k2
-1
0
1
-l2.
3h2/2 - k2/2 + l2 2k2
=
—Aï 2 + l2
in succession by (111), (111), (111) and (111),
(122), (022), and (320).
The integers in (220) and
(022) are reduced to (110) and (011), respectively, because both sets contain a common factor of 2.
With this reduction, we can conclude that
the close-packed monolayers of oxygen atoms in kyanite are parallel to planes with indices (110), (122), (011) and (320).
•
(P2.11) Problem: The close-packed monolayers of oxygen atoms of
the
sapphirine structure parallel (111), (111), (111) and (111) of its face-centered subcell.
Show that these monolayers parallel (100), (052),
(101) and (052) of the sapphirine structure.
69
(P2.12)
Problem:
The crystal structure of tremolite, a calcic amphibole
of C a 2 M g 5 ( S i ^ O ! i ) 2 ( 0 H ) 2 composition, bears a close structural resemblance w i t h that of the calcic pyroxene diopside, C a M g S i 2 0 s , w h e n viewed down [010] w i t h a , C, and (5 being nearly the same in both minerals.
However,
the cell dimensions of the two minerals differ in that the b - c e l l edge of tremolite is double that of diopside.
W h e n Warren
(1930) solved the
structure of tremolite, he took advantage of these relationships and derived the basic structural unit (a double chain) in the amphibole structure by reflecting the diopside structure over a plane perpendicular to [010].
In a paper on this choice of basis vectors, Whittaker and Zussman
(1961) have observed that although
Warren's
choice,
Dj =
{aijbj.Cj},
illustrates the relationship to the diopside structure, it does not conform w i t h the conventional choice of basis, D 2 = { a 2 , b 2 , c 2 } ,
(1)
»2
=
»1 ~
b2
=
b,
c2
=
Cj
defined by
Cl
.
Using the cell dimensions (Oj = 9.78A, b j = 17.8A, Ci = 5.26A. 0! = 73.97°, o! = y x = 90°) determined by Warren, show that the cell dimensions of the conventional cell are o 2 = 9.74A, b2
=
17.8A, c 2 = 5.26A, P 2 = 105.23°, o 2 = Zz = 90°.
(2)
A Ca-rich amphibole like tremolite Ca-poor amphibole adopted by Warren.
is commonly exsolved
lamallae developed along
(3)
Warren's
(001) of the cell
Show that these lamellae parallel
of the conventional cell (cf. Ross et at.,
(101)
1969).
structural analysis of tremolite showed that one of
the Si atoms in the double chain has coordinates 0.01) t .
with
(0.29,
0.08,
Show that the coordinates of this Si atom in the con-
ventional cell are (0.29, 0.08, 0.30)*.
(E2.19) Example - A calculation of the cell dimensions of kyanite assuming its o x y g e n
atoms are c u b i c c l o s e - p a c k e d .
If we assume that the
face-
centered subcell displayed in Figure 2.4 for kyanite has cubic geometry
70
(i.e., the oxygen atoms in kyanite are ideally cubic close-packed so that a
2 ~ b2 = c2, a2 = B2 = 2"2 = 90°) and the oxygen atoms are in
contact
along the face diagonals of the cell, then a2 = 2/2r0 where r 0 is the effective nonbonded radius of an oxygen atom.
If we equate the volume
3
of this cell, v = 16/2r0, with that obtained by evaluating the determi3
nant of G 2 , then 16/2r0 = 58.719A3.
Solving for r„, we get r, = 1.374A.
Our problem is to determine the cell dimensions of kyanite assuming that its oxygen atoms are ideally cubic closest packed each with an effective radius of 1.374A.
As the cell edge of such a cube is 2/2r 0 , then its cell
edges are given by cr2 = 2/2" x 1.374A = 3.886A.
The metrical matrix for
this ideal structure with a2 = b2 = c2 = 3.886A and ot2 = 62
=
=
90.0°
is obtained by evaluating (2.22):
Gi = T t G 2 T 3/2
-1/2
1
15.1010
0.0
0
2
0
0.0
-1
0
1
0.0
0.0
52.8535
-15.1010
-15.1010
60.4040
15.1010
-78.5505 Solving G! for the cell dimensions
-1
0.0
-1/2
2
0
1
0
1
15.1010
0.0
-7.5505 0.0 30.2020
of the
ideal
structure, we obtain t^ = 7.270A, bx = 7.772A, Pi = 100.89° and ïj = 105.50°.
0
0.0
close-packed
kyanite
= 5.496A, c^ = 90.0°,
These values show a close correspondence
with those measured for kyanite (E2.17), indicating the centers of the oxygen atoms in the structure define rather well a face-centered cubic lattice. (P2.13)
(1)
• Problem:
Evaluate the determinant of the metrical slightly
distorted
subcell of
sapphirine
matrix and
G2
for
the
show that its
volume is v2 = 66.125A3. (2)
Equate the volume obtained in (1) with that of a cubic face3
centered cell, 16/2r0, and show that r 0 = 1.430A.
71
2.5: >cal
A set of direct * * * * D
-
Lng from a k
D -
(a,b,c) and
(a ,b ,c } basis vectors each common
origin,
0.
The
unit
is directed along I so that c = ck, i
:ed in the (a.c)-plane perpendicular to C it a = osinPi + ocos&j and j is directed * * * b so that b = D J. No significance be attached to the relative lengths of the * basis vectors.
D
(3) Assuming that the cell edge of the cubic cell is 2/2r0 and that r 0 = 1.430A, show that the metrical matrix for an ideal closepacked sapphirine structure is 130.896
0.0
0.0
204.525
-65.448
0.0
Gi =
-65.448 0.0 98.172
(4) Calculate the cell dimensions of the sapphirine assuming that it consists of a cubic close-packed array of oxygen atoms of radius 11.44A,
1.430A.
Compare
these calculated dimensions
= 14.30A, cx = 9.91A,
= 125.3°, a1 =
(Oj = = 90°)
with those given in P2.10. A DESCRIPTION OF THE GEOMETRY OF A CRYSTAL IN TERMS OF A CARTESIAN BASIS It is often useful to define a natural basis D = {a,b,c} of a crystal in terms of a cartesian basis.
We shall choose the cartesian basis C =
{i,j,k} such that k is in the direction of C, j is in the direction of C X a and i is set perpendicular to the plane of k and j so as to complete a right-handed cartesian basis set (Figure 2.5).
For this setup of the
cartesian basis, there must exist real numbers a., such that the natural basis D for a crystal can be expressed as
72
a = Q u i + o 3 jk (2.27)
b = a 1 2 i + cr22j + o 3 2 k c = oJ3k
Note that by the way in which the C-basis (in particular in regard to the handedness of D
and C )
is defined in relation to the
° n s °2 2 and o 3 3 must all be positive.
D-basis,
Thus, the change of basis matrix
A from D to C is given by
A =
[a],
[e],
[b],
=
On
oi2
0
0
o22
0
o3i
O3 2
033.
(2
To find the entries of this matrix, we use the following circuit diagram (compare with 2.22)
[r ] D G
[r]c \
t \ I iJ A" T " [r]r
[r] D and obtain
G = AtI3A = AtA
(2.29)
Expanding (2.29) we have
a2 G =
b2
occosP
becosa
2 ^ 2
»11 + Oji
alia12
abcost ac cosfi
abcos?
+ o31o32
= AfcA
becosa c2
o,,a,, + a 3,o3 2
2
2
o12 + o22 + a32
1O33 (2.30)
o32o33 2 °33
By equating corresponding elements of (2.30), expressions are found from which the a., entries of A shall be deduced.
We begin by observing that
2 a33 = c 2 and so o 3 3 = c.
Next, replacing o 3 3 in both o 3 2 o 3 3
by c, we find that 0 3 1 = ocosB and o 3 2 =
73
facosa.
and O31O33
Replacing o 3 1 in
2 °n
+
cr32
2 °31 are
= ai
by acosf, we find that O n = osinP.
replaced
by
crsinfJ,
acos(5
and
When a l l t
b cosa,
o 3 1 and
respectively,
(cosi - cosacos|3)/sinfS is replaced by -cosi sina (T2.8), we *
o 12
=
by
-fasinacosJT
-bsinacosi .
2
and
find 2
that 2
Finally, replacing a 1 2 and o 3 2 in o 1 2 + o 2 2 + o 3 2
and facosa, respectively, and simplifying, we find that
o 2 2 = fasinasini .
When these results are substituted into (2.28), the
A matrix becomes denoted a(i is defined
to be the mapping cc3(r) = 1, then ni is denoted
We denote 1/ simply as /'. The names and symbols for some represen-
tative rotoinversions are given in Table 3.2. (1976), we
Following Boisen and Gibbs
assign to n, the turn angle and rotation axis of n.
orientation symbol for n is taken to be that of n. a quarter-turn inversion with the axis of
its
directed along a and with a turn angle of 90°.
Thus, associated
denotes quarter-turn
Likewise, 3 denotes a
third-turn inversion whose rotation axis parallels C.
96
The
Figure 3.3: The action of a rotoinversion a/ on an arbitrary point r e S where 0 denotes the origin, a is a rotation about I with turn angle p and / is the inversion isometry. The vector r is mapped onto —r by / (i.e., /(r) = - r ) and a maps (-r) onto S = a(-r) - a 0 ( f ) ) ~ ai(r). Hence, the rotoinversion isometry ai maps r onto s. The turn angle and the rotation axis of o/ are inherited from a.
Figure 3.4: The action of a reflection isometry m = /2 on an arbitrary vector r t S where 0 is the origin and m is the mirror plane perpendicular to the rotation axis £ of a half-turn 2 over which the vector r is reflected. The vector r is mapped onto s by 2, s is mapped onto -S by / so that /2(r) = -s. Hence ¡2 is equivalent to a reflection m of the vector r directly over the plane m onto -S such that m(r) = -s.
Figure 3.3 shows the effect of a rotoinversion o/ on a point r e S where a has a turn angle of p°.
As the inversion sends r to —r, we observe
that o/(r) = o(/(r)) = a(-r).
Then a rotates —r through a turn angle of
p mapping —r onto s as shown in Figure 3.3. So far we have only considered rotoinversions of the form a/.
This
does not result in loss of generality since, as we shall now show, ia = ai for any rotation a.
Let V denote a vector in 5 and let a denote a
rotation such that a(V) = W.
As -v lies on the same line as V, a(—V)
must lie on the same line as W but point in the opposite direction such that
a(-V) = —W.
—ot(v) = a(—V). /a(V) .
Next, multiplying a(v) = W by -1, we observe that
Hence, a/(V) = a(/(v)) = a(-V) = -a(v) = /(a(V)) =
Therefore, a/ and ia are the same mapping.
that a and / commute.
Since a/ = /a, we say
Hence / commutes with all rotations.
As we shall
see later, isometries do not in general commute and the fact that / commutes with each rotation is an important property of /. All rotoinversions, with the exception of 2, leave exactly one point 97
/(c) W(b) /{aï
/'(c)
Figure 3.5: A collection of vectors that are images of an arbitrary vector r t_S under the point isometries that comprise a 6 inversion axis paralleling £.
in S fixed.
Figure 3.6: An illustration that an inversion isometry i changes the handedness of a basis from right to left. (a) A right-handed basis D = {a,b,c} emanating from an origin 0. (b) The images of a, b and c, {/'(a) ,/(b) ,/(c)} under /. (c) The figure in (b) rotated so that /'(a) and /(b) are parallel to a and b, respectively, in (a). Observe that the basis vectors in D = {/'(a) ,/(b) ,/(c)) are left-handed illustrating that an inversion isometry changes the handedness of a set of basis vectors.
The 2 operation leaves a plane of points fixed, as illus-
trated in Figure 3.4. Rather than viewing 2 as the composition of 2 and /', it is simpler to view the operation as a reflection about the plane of points left fixed by 2.
By a reflection we mean that each point and
its image lie on a line perpendicular to the plane such that the plane bisects the line segment between them. Because of this fact, 2 is almost always referred to as a reflection
isometry and is denoted by m.
thermore, the plane of fixed points is called the mirror
plane m.
FurThe
orientation symbol assigned to m is inherited from that of the axis of the perpendicular half-turn part of the operation.
For example,
^^^m
denotes a reflection of space over a mirror plane that is perpendicular to 2a + b , whereas m denotes a reflection of space about the plane that is perpendicular to C. (P3.1) Problem:
Determine the names and symbols of the point isometries
o that map the vector r in Figure 3.5 onto r , s, t , u, v and W , assuming that the rotation axis £ of a parallels C. 98
Consider the right-handed set of basis vectors D = {a,b,c} displayed in Figure 3.6(a).
The images of these vectors under the inversion is the
set D = {/'(a), /(b), /'(C)} (Figure 3.6(b)).
If we orient D with /'(a) on
the left and /'(b) on the right, then /'(c) will be directed downward (Figure 3.6(c)).
Consequently, the inversion transforms a right-handed basis set
to a left-handed one (see Appendix 4) .
Since rotations do not change the
handedness of a basis, the net effect of a rotoinversion ai is to change the
handedness.
basis.
Hence, all rotoinversions
change the handedness of a
One important consequence of this is that no isometry
is both a
rotation and a rotoinversion.
(E3.3) E x a m p l e
- The
inversion m a p p i n g
the composition of two successive
is its o w n
inversions
about
inverse:
Show that
a
point
common
is
equivalent to the identity.
Solution:
Since /'(r) = - r for all r E S , then /'(/'(r)) = /'(-r) = 1(r).
Hence /'/' = i2
= 1.
•
SYMMETRY
(D3.4) Definition:
The symmetry
ELEMENT
element
of a point isometry a is defined
to be the set of all points in space left fixed by a, i.e., a point p e S
is on the symmetry element of a if a ( p ) = p. Let a denote a rotation other than the identity with a rotation axis
I.
Since each point p along i is left fixed by a and every other point
in S is moved, i is the symmetry element of a. by the identity, and so S
Every point p E 5 is fixed
is the symmetry element of the identity.
As
a plane of points is left fixed by a reflection, this plane, referred to as the mirror plane, is the symmetry element of the reflection.
Because
all other rotoinversions
element
each fix a single point, the symmetry
of these isometries is a point.
It should be noted that our
of symmetry element differs somewhat from that used
definition
in the ITFC (Hahn,
1983). In isometry
general,
the
type
of
symmetry
a reveals what type of point
a ( p ) = p for all p £ S,
element
then a is the identity.
of a is a line I, then a is a rotation. a plane, then a is a reflection.
possessed
isometry a is.
by
a
point
For example, if
If the symmetry element
If the symmetry element of a is
Finally, if the symmetry element of a
is a single point, then a is a rotoinversion other than 2. 99
DEFINING
The
symmetry
SYMMETRY
of an object is often described intuitively by such
phrases as "the object is well-balanced or well-proportioned" or that "it consists of a pattern that is repeated at
regular
point, line or plane or along a direction in space." of phrases are too ambiguous for our purposes.
intervals
around
a
However, these types
By using isometries, we
can define symmetry with sufficient rigor so as to bring powerful mathematical tools to bear on the subject. Consider an object in space occupying the subset of points B in S. Let a denote an isometry.
By a(B) we mean the set consisting of all of
the images of the points in B .
That is,
a(B) = (o(b) | b
If b2,C 2 } to be the set of vectors emanating from p such that a 2 parallel to aj and cr2 = Oi, b 2 is parallel to bj and b2 parallel to Cj and c 2 = c t .
= bx
is
and c 2 is
Then the set of end points of the vectors
in
LQ
= {uai
is described in terms of D2 {q + ua2
+ ybj + wCi
| u,v,w
t Z}
as + vb 2 + w c 2
| u,v,w
E
Z} ,
where q is the vector emanating from p with terminus 0. If we let Ln = {ua2 + v b 2 + w c 2 I u,v,w E Z}, then the set of points in L n U Ux equals 2 {q + l2
|
E
LD
To show that a maps our new lattice Ln U2 show that if SL2
e
L n , then a(H 2 ) L>2
E
Lo • u2
)
.
into self-coincidence, we shall By adding and subtracting q,
we have a(d 2 ) = a(q + i2
- q) .
Since the origin p is fixed by a, a is a linear mapping with respect to the vectors emanating from p, and so a(q + l 2 - q) = a(q + l 2 ) - a(q) . Since end points q + l2 end points in L n . •J i
and q are both in Ln
Therefore, t
"(q +
, a(q + H 2 ) and a(q) have
- q +
tt and a(q) = q + i2 131
,
o(H 2 )
= o ( q + H2) - o ( q ) t t! = [q + n 2 ] - [q - ii] t2
-
H2
Since a is an isometry, the fact that a(Ln that a(Ln
) = Ln
U 2
L/ 2
E
L,
"D 2
L>2
and so Ln is mapped I/;
•
) is a subset of Z_n implies U2
into self-coincidence
by a.
Thus, if a lattice is mapped into self-coincidence by a, then the origin of the lattice can always be chosen as a fixed point of a. (T4.15)
Theorem:
•
If C is a crystallographic point group, then C has
a finite number of elements. Proof:
Let LQ
denote the lattice that is mapped into self-coincidence
by each of the isometries in C.
By T4.14, without loss of generality,
the origin 0 of L ^ may be taken to be a common point left fixed by each of the isometries in C.
Consider a ball centered at 0 with large enough
radius so that it contains all three basis vectors a, b , c e LQ
and let
a be an element of C.
Since a does not stretch vectors, and
a(Lp)
and a(c) must also be vectors in L^
= Lp,
a(a),
within the ball.
a(b)
(Newman, 1972, p.90).
lattice points
of L ^
in the ball
Consequently, there are only a finite number of
choices for ot(a), a ( b ) and a ( c ) . a(b),
contained
Moreover, inasmuch as the radius of the ball is finite,
there are only a finite number of
{a(a),
since
Since a is completely determined by
a ( c ) } , we conclude that there is only a finite number of
distinct point isometries in C that leave L p invariant. (D4.16) Definition:
•
When a group C is finite, the order of C , denoted
#(C), is the number of distinct elements in C. For example, since 322 consists of 6 elements, we write #(322) = 6. (P4.4) Problem: (T4.17) Theorem:
Determine #(422). Let a denote a crystallographic point isometry.
Then
the turn angle p associated with a is a multiple of either 60° or 90°. 132
Proof:
Since a is a crystallographic point
into self-coincidence.
Let D = { a , b , c }
Since a(Lp) = L Q , a ( a ) , a ( b ) ,
and a ( c ) are in
lattice LQ such that o maps LQ denote a basis for L LQ and so [ a ( a ) ] p ,
D-
isometry, there exists a
[ a ( b ) ] ^ j and [ a ( c ) ] ^ have integer coordinates.
these triples are the columns of M^(a), all of the entries of integers.
Consequently, the trace of
is an integer.
Since are
By TA3.6,
tr(M n (o)) = ±(1 + 2cosp)
(4. sign when a
where the "+" sign is used when a is a rotation and the is a rotoinversion.
The solutions to (4.1) given that tr(M 0 (a)) = N
for
some
integer N
are enumerated
in Table 4.1.
Note that
since
|cosp| < 1, we have the inequalities -1 < 1 + 2cosp < 3
and
-3 < -(1 + 2cosp) < 1
.
An examination of Table 4.1, where those values of N that satisfy these inequalities are listed and the corresponding p values are found, reveals that p is always either a multiple of 60° or 90°.
The point
isometries associated with each p value is also shown in Table 4.1. Table 4.1:
•
Solutions sets of the turn angles p for any crystallographic point isometry a. —(1 + 2cp) Solutions
(1 + 2cp) Solutions
N
cp = (/V - l)/2
p
o
-1
-1
180°
0
-i
±120°
1
0
±90°
2
i
±60°
3
1
0°
N
a
2
cp = -(/V + 1 ) / 2
p
0
a
1
-3
1
0°
-2
4
±60°
6,6*1
4,4-1
-1
0
±90°
4,4-1
6,6*1
0
-i
±120°
3,3*1
1
1
-1
180°
133
m
The 16 isometries found in Table 4.1 will serve as the elements for all of the crystallographic point groups. that such a group G is a bona
fida
However, before we can conclude
crystallographic point group, we must
show that there is some lattice that every element of G maps into selfcoincidence.
In this chapter and the next we will find all of the finite
groups that can be constructed from these isometries.
In Chapter 6, we
will find a lattice that is left invariant for each of these groups. MONAXIAL ROTATION The
structure
of
a group C
GROUPS
can be better understood by studying
certain special subsets of C called subgroups. (D4.18) Definition:
A subset H of a group C is a subgroup
of C if, under
the binary operation of C , H is a group. For example, in Chapter 3, we observed that 322 has several subgroups including 3 = {
1
,
2 - {1,1-^^2}.
3
,
3
difficult
to
"/0>2 =
{ l , ^ } ,
O.t110^}
and
We confirmed that these were subgroups by creating
their multiplication tables. are
=
see
However, some of the rules defining a group
directly
from
such
a
table.
The
rule
of
associativity is not readily verifiable from a simple inspection of the table.
The determination of which element is the identity and which el-
ement is the inverse of a given element can be seen from a table, but it is somewhat tedious.
Furthermore, if a subset of a group is very large,
then creating its multiplication table can be impractical. theorem
eliminates
most
of
these
difficulties
The following
in the case of finite
groups.
(T4.19) Theorem:
If H is a finite nonempty subset of a group C ,
then
H is a subgroup of C if and only if H is closed under the binary operation of C . We
will
not
prove
T4.19
here
but its proof can be found in any
standard modern alegbra text (e.g., Herstein, 1964). (E4.20) Example - 222 is a s u b g r o u p of 422:
Consider the subset
O,2V00hW°h}
222 =
134
Figur*
4.2:
The multiplication table for the
group 222 under composition.
[100]2
2
222
1
1
2
2
2
1
[100]2 [010]2
[100] 2
[010]j
[010]2
[100]2
1 2
2 1
[°10l2 [ioo]2
[10012 [010]2
[010]2
and show that it is a subgroup of H22 (see P3.15). Solution
To determine whether 222 is a subgroup of H22, we construct the
multiplication table shown in Figure 4.2. of elements in 222,
we know that 222
Since we have a nonempty list
is a nonempty set.
entry in the table belongs to the set 222,
222
is closed under the binary
operation (composition) of 422 and so is a subgroup. H
Also, since each
In other words, if
is a nonempty subset of a group (G,*), then (H,*) is a subgroup of G
if each entry in the multiplication table of H is an element of H.
(E4.21)
Example:
•
Let K denote a crystallographic point group and let
D denote a basis.
Then the set of matrices C = M n ( K ) = {M n (a) | a E K) D D
forms a finite group under matrix multiplication. set (T4.15), then M Q ( K ) must be a finite group. of
C
Since K is a finite Let H denote the subset
consisting of all matrices M in C such that det(M) = 1, i.e., M
represents a rotation isometry.
Show that H is closed and therefore a
group under the binary operation of C . Solution: I3 £ C . Mj,
Since 1 t K
(it is the identity element of K) , then M p O ) =
But det(I 3 ) = 1 and so I 3 c H.
M 2 £ H.
Then
MIM 2 E C
det (Mj )det (M 2 ) = 1 • 1 = 1. the binary operations of C .
since
C
Therefore, H is nonempty. is
a
group
Hence, MiM 2 £ H and so H
and
Let
detiM^j) =
is closed under
This result also shows that the composition
of two proper crystallographic operations is a proper
crystallographic
operation.
(P4.5) Problem: K
•
Let a and B be elements of a crystallographic point group
(E4.21). 135
(1)
Show that a(5 is a proper operation when a and 3 are both improper operations.
(2)
Show that ct$ is an improper operation when a is a proper and B is an improper operation.
(D4.22) Definition:
Let g denote an element of the group G
binary operation *.
The nth
is a positive
the
power of g , denoted g " is defined to be
g " = g * 9 * • •* g where n
under
(n g's)
When n = 0, g ^
integer.
is defined
to
be
identity element of C and when n < 0, g " is defined to be (g ^)
the that
is g" = o " 1 when n < 0.
* g"1*
•* g " 1 )
9's)
The usual rules of exponents hold true for the powers of
an element g e C
including the following: n
(1)
g
(2)
(g )
(E4.23) Example:
Let C
* g
m
= g
n + m
= g
r
for all r>, m
for all n,
m
E
E
1
,
1 .
denote a crystallographic point
group.
Let
g E C and define H = {gn
| n s Z)
,
then show that H is a subgroup of C. Solution:
According to T4.19, we need only show that H is closed under
composition.
Let X , y E H.
n and m such that x = g1
By the definition of H, and y = gm.
there exists integers
Hence,
n m n + m xy = g g = g
Since n + m is an integer, x y E H.
(D4.24) Defi nition: subgroup
Hence, H is a subgroup of C .
Let (G,*) denote a group and let g E G .
of G generated by g, denoted , is defined to be
136
The
c
cyclic
= ig" I n z Z) We will now justify calling a subgroup. that when C
In (E4.23) we showed
is a crystallographic point group, then is a subgroup.
In the next problem, you shall be asked to prove this fact in general.
(P4.6) Problem: subgroup of C
Show that if g E C where C is a group, then is a
(do not assume that C is finite).
(D4.25) Definition:
Let C denote a group and let g z C.
If g' = e for
some positive integer /' where e is the identity of C , then the smallest such positive integer is called the order of g and is denoted o(g).
Let g z C where C is a group such that there is a positive integer /' such that g' = e, the identity element of C.
= {g,g 2 .g 3 ,•••,g
Let k = o(g).
Then
= e} .
This means that any element of {g" | n z Z} can be written as g' where 1 < j < k.
For example, g ^ = g ^
gg
j
and g
k +1
= g since g
k - 1
k + 1
o(g).
= g
k
= g g
Furthermore, it is straightforward distinct.
^ since
k
= e
= eg =
to
show
,
g.
that
g,g 2 ,...,g
are
That is, if g' = e for some positive integer /', then # ( 9 )
=
A cyclic subgroup of a crystallographic point group is a set of
isometries having a common axis.
These form such symmetry elements as
an n-fold rotation axis or rotoinversion axis.
(E4.26) Example - T h e elements of = 4:
Let C denote the group of
all point isometries leaving the origin fixed and consider a quarter-turn 4 z C.
Since 41* = 1 and 1 is the identity element of C , = {4,4 2 ,4 3 ,4* = 1} .
We give this cyclic group the symbol 4 and note that the elements of this group define a 4-fold axis.
Since all of these proper rotations fix the 137
same axis, t is an example of a proper monaxial group. 43
is usually written in the equivalent form 4 ^ and 4 2
By convention, is written as 2
to conform with the convention adopted with respect to the turn angle in Chapter 3.
Hence, 4 = = ( M ^ ^ "
(D4.27) Definition:
1
}
.
A group consisting of rotations that fix a
axis is called a proper
monaxial
common
group.
A finite proper monaxial group C is cyclic and is generated by the rotation
in
C with the least non-negative turn angle.
generator for U.
Thus 4 is the
If C is a proper monaxial crystallographic point group,
then by T4.17, a generator for C can be found with a turn angle 0°, 60°, 90°, 120° or 180°.
This can be shown by observing that rotations with
turn angles greater than 180° generate groups that include rotations with turn angles less than 180°. a3
is a rotation of 90°.
For example, if a is a rotation of 270°, then A complete list of all of the possible proper
monaxial crystallographic point groups is given below:
1 =
=
{1 V
V
£
z}
V
=
{1}
2 =
=
(2
V
E
Z} =
{1,2}
3 =
=
{3 V
V
£
Z} =
{1,3,3 - 1 }
4
=
=
{4 V
V
E
Z} =
{1,4,2,4'h
6 =
=
{6 V
V
E
Z} =
{i.e.a^.s"1^
We observe that each of these proper monaxial groups define an
n-fold
axis where rt = 1, 2, 3, 4 and 6. Now that we have all of the possible proper monaxial crystallographic point groups, we can use the following theorem to obtain all of the possible improper monaxial crystallographic point groups.
(T4.28) T h e o r e m :
( T h e improper
point
group
generating
theorem.)
If
/ is an improper crystallographic point group, then there exists a proper crystallographic point group C such that either
(1)
(2)
I =
C
{gi
| g
I = H U
U E
Gi,
where
is
i
the
inversion
(here
C } ) , or
(C \ H)i
where H is a subgroup of C such that
138
Gi =
#(C)/#(W) = 2 (here (C \ «)/ = {gi | g e C and g | H)). Furthermore, all of the sets constructed from a proper crystallographic group C as in (1) or (2) are groups and hence improper
crystallographic
point groups. By the symbol "U" used in I = C U Ci, we mean the union of the two sets C
and Ci where the union of two sets A
and B,
A U B is defined
to be the set consisting of all of the elements of A
together with all
of the elements of B . not in H. from C . group
By (C \ H ) we mean the set of elements in G but
The set (C \ W ) is obtained by deleting each element in H A subgroup H of C such that #(G)/#(H) = 2 is called a halving
of C
(since it has half of the elements of C).
The proof of T4.28
is given by Boisen and Gibbs (1976) .
(E4.29) Example:
Use T4.28 to find the improper crystallographic point
groups for the case where C = t. Solution:
Applying part (1) of T4.28, we obtain
C U Ci = 4 U ti = {1,4,2,4" 1 } U O ,4,2,4~^}i = n,4,2,4" 1 ,1/,4/,2/,4" 1 /} = {1 ) 4,2,4~ 1 ,/,4,m,4~ 1 } . This group contains a 4-fold rotation axis, 4 = {1,4,2,4
perpendic-
ular to a mirror plane, m = {1,m}, and is consequently designated 4 / m read "4 upon m".
Applying part (2) of
{1,2} is the only halving group of of C .
T4.28,
we
note
that
=2
2 =
since both 4 and 4 ^ generate all
Then
H U (C \ H)i
H =
U (4 \ 2)/ = {1,2} U ({1,4,2,4^} \ {1,2})/
= {1,2} U {4,4"1}/ = {1,2,4M"1/} = £ 1,2,4,4 _1 > .
139
This crystallographic point group is designated 4 because it is the cyclic group generated by 4.
We also
observe that T4.28 states the groups
constructed using (1) and (2) are improper crystallographic point groups and so there is no need to examine whether these groups obey the rules of a group.
•
(E4.30) Example - Derivation of the possible improper point groups based on 3:
Use T4.28 to find the improper crystallographic point groups for
the case where G = 3.
Solution:
Applying part (1) of the theorem, we obtain = {1.3.3" 1 } U
3 U 3i
{/.M"1}
= {1,3,3~\i,3Xh •
Since this is a cyclic group generated by 3, the group is denoted by 3 Since 3 has an odd number of elements, it has no halving
read "three bar".
groups and therefore (2) does not apply.
Note that #(C U Gi) #(G).
if
C
is
a proper
•
crystallographic
point
= 2#(C) and if H is a halving group of G , Furthermore,
the
nature
of
G U Ci
differs
group,
then
U (G\W)/') = from
that
H U (G\W)/ and G in the sense that G U G/' contains the inversion. reason C\H.
H U (G\H)/
does
not
The
contain /' is that 1 is not an element of
A point group containing i is called a centrosymmetric Note that when C
of
group.
is monaxial, then G U Gi and H U (G \ H)i
are
also monaxial with the same axis.
In the case of C U Ci, we observe that
if a E G U Ci,
g for some g E C or a = gi
g £ G.
In
then
either
either case
a
a = and
g
have
the
same
for some
axis.In the case of
H U (C \ H)/, if a E H U (G \ H)/', either a = g for some g E H, plying that a and g have the same axis, or a = gi where g E C \ H, implying that a and g have the same axis.
imagain
Therefore, we see that the
set of axes in any improper crystallographic point group is the same as that of the proper group from which it is derived.
(P4.7) Problem:
Use T4.28 to find the improper crystallographic point
groups for the case where G = 2.
Show that
140
(2 U 2/ is denoted by 2/m).
Show that H - {1} is a halving group of
2 = {1,2} and that / U
(2 \ 7)/ = {1 ,m} .
This group is called m because it is a cyclic group generated by m. (P4.8) Problem:
Use T4.28 to find the improper crystallographic point
groups for the case C = 7.
Show that
7 U 7/ = {1,/}
(7 U 7/ is denoted 7).
(P4.9)
Problem:
Explain why 7 has no halving group.
Use T4.28 to find the improper crystallographic point
group for the case C = 6.
6 U 6i =
(6 U 6i is called 6/m reflection plane).
Show that
{l,6,3,2,3" 1 ) 6" 1 J /,6 ) 3,m J 3" 1 ,6" 1 }
because it has a 6-fold axis perpendicular to
a
Show that 3 is a halving group of 6 and that 3 U (5 \ 3)i = O ^ S " 1 , ^ , « ; " 1 }
•
This group is denoted 6 since it is ). We have now derived all 13 of the possible monaxial crystallographic point groups.
These are listed and their derivations summarized in Table
4.2. Matrix
representations
and basis v e c t o r s :
In order to obtain a matrix
representation for each of the point isometries for a given group, we need to select a basis for each group. To accomplish this, we will define, for each crystallographic point group C , a set of bases such that
the
matrix
representations
of
the
isometries is the same for any basis in the set and such that the matrices are of a simple form.
In fact, each entry of the resulting matrices will
be either 1, 0 or —1.
In chapter 6 we will show that every lattice left
invariant by a point group C will contain a sublattice that has a basis
141
Table 4 . 2 :
T h e 13 monaxial c r y s t a l l o g r a p h i c point g r o u p s and t h e i r orders d e r i v e d from the p r o p e r monaxial c r y s t a l l o g r a p h i c point group
Improper Monaxial Point Groups
Proper Monaxial
Halving
Point Groups
Groups"
Containing / (centrosymmetrie)
C
HC)
1
l
2
2
3
3
6
C U CI
H
none
1 none
#(C U
Not Containing /'
H U (C \
Ci)
H)i
1KH U (C '
1
2
none
2/m
4
m
3
6
none
8
Ü
4
12
6
6
4
2
t/m
6
3
6/m
of the type we define for C in this chapter and the next.
2 —
Since such a
sublattice will be called a primitive lattice, we will use the letter P to denote these bases. We
begin
by
considering
the
nth-turns
crystallographic point groups in Table 4.2.
of
the
monaxial
In all cases we will assume
that the bases described are right-handed.
1 (identity):
Since 1 is represented by the identity matrix for
every
basis, any basis can be chosen.
2 (half-turn):
For n > 1, we shall choose C to be any nonzero vector in
the positive direction of the rotation axis.
The a and b vectors
are
chosen to be any non-collinear, nonzero vectors in the plane perpendicular to c .
Since any vector perpendicular to the rotation axis of 2 will be
mapped to its negative, '-1 Mp(2) =
0 0
142
0 -
o' 1
0
0 1
.
3 (third-turn):
As in the case of a half-turn, c is chosen to be a nonzero
vector in the positive direction of the rotation axis. As 3 ( a )
to be any nonzero vector perpendicular to C. with a , we choose b = 3 ( a ) .
We then choose a is not collinear
With this choice of basis, we recall from
our discussion of 322 in Chapter 3 that 3 ( b ) = - a — b and so
0 - 1 0 1 - 1 0
M p (3) =
0
4 (quarter-turn):
(4.1
0
1
As before we choose C to be a nonzero vector in the Also, we let a be any nonzero
positive direction of the rotation axis.
vector perpendicular to C and let b = 4 ( a ) .
For this choice of basis,
we obtain 0 - 1 0 Mp(4) =
6 (sixth-turn):
To keep the number of basis types small, we choose as
the basis for 6 that which is used for 3 , where C is chosen as a nonzero vector in the positive direction of the rotation axis of 6 . a + b and 6 ( b ) = - a .
Then 6 ( a ) =
Hence, "l
-1
o"
Mp(6) =
(E4.31)
Example:
Find M p (3) = { M p ( 3
of Hp (3) and recognizing that Hp(3k)
)
| k e Z)
by finding the powers
(.Hp(3))k
After finding Mp(3),
=
find M p (3) U M p (3)M p (/).
Mp(3) Solution :
By (4.1),
Mp(3 )
II
2
"o
-1
o'
1
-1
0
0
0
1
2 =
143
-1
1
o"
-1
0
0
0
0
1
=
Mp(3"1)
;
II
Mp(3 ) =
0
-1
o'
1
-1
0
0
0
1
3
"l
0
o"
0
1
0
0
0
1
=
Mp(1)
Hence, 1 Mp(3) =
0
0
0
-1
0
0
1
0
0
0
1
-1
0
1
0
0
1
>
,
-1
1
0
-1
0
0
0
0
1
Mp(a)Mp(/) = -Mp (a) for any point isometry
Mp(3)M p(/)
{"Mp
=
(4.2)
a
(1),-Mp(3),- Mp(3"
Hence "-1
0
0
-1
0
0
0
-1
Mp(3)Mp(/) =
Then
Mp(3)
consists
of
o'
1
0
-1 y
1
0
0
"l
-1
0
1
0
0
0
0
-1
0 -1
]
o" (4.3)
the matrices in (4.2) together with those in
(4.3).
(P4.10)
o
Problem:
Then find M p ( n )
Find M p ( n ) = { M p ( n U Mp(n)Mp(/') .
)
| k t Z) for n = 1, 2, 4,
6.
For each C = n and each halving group H
of C that exists, find
Mp(tt U (C \ H)i) = M p ( W ) U (Mp(C) \ Mp(W))Mp(/).
Equivalent
Points and Planes:
We defined the symmetry group G of an
object to be the set of all isometries that map the object into coincidence.
self-
Utilizing G we can impose an "equivalence" on the points
in S.
( D 4 . 3 2 ) Definition: and y
Let G denote a group of isometries.
in S are said to be
C - e q u i v a l e n t
if there exists
a
The points X e C such that
a(X) = y .
In the case where C is the symmetry group of an object 6 , then the intuitive interpretation of C-equivalent points is that if x and y are C-quivalent, then the object B
appears the same in every respect to a
person viewing the object from either point x or point y .
144
The notion of C-equivalent points is a generalization of the notion of equality.
That is, while X and y may be d istinct points, the statement
that they are C-equivalent expresses the idea that in some specific sense they are equal.
This is similar to our usual handling of fractions in
arithmetic where we think of the fractions 2/3 and 4/6 as being "equal" even though they are clearly not identical.
If C-equivalence is to mimic
equality, we would hope that the basic properties of equality hold. (T4.33)
Theorem:
Let C denote a group of isometries and let x ~ y
denote "x is C-equivalent to y " .
Then
(1)
X ~ X for all X E S
(2)
For all X, y E S,
(3)
For all X, y, Z E S, if X ~ y and y ~ Z, then X ~ z (transi-
(reflexive property) ;
if X ~ y then y ~ X (symmetric property) ;
tive property) . Proof:
Since C is a group of isometries, 1 t C.
all X E 5 , we have X ~ x for all X E S . in S such that X ~ y .
Let X and y denote elements
Then there exists a E C such that a(X) = y .
C is a group, a ^ E C.
Since
Then a'VtX))
=
a" 1 (y)
(a_1a)(x)
=
a-1(y)
1(X) =
a_1(y)
X
Hence y ~ X.
Since 1 (X) = x for
=
a_1(y) .
Let X,y,Z E S such that X ~ y and y ~ Z. Then there exists
a, 3 E C such that a ( x ) = y and £(y) = Z.
Then
ga(X) = B ( o ( x ) ) = B(y) = Z. Since C is a group, it is closed and so &a E C.
Therefore X ~ Z.
Any relation defined on the elements of a set satisfying the three parts of T4.33 is called an equivalence lations are fundamental principles of concept.
relation.
Since equivalence re-
to any true understanding of the mathematical
crystallography, we have devoted much of Appendix 7 to this
Those who are unfamiliar with this concept should
appendix carefully. 145
read this
•
Equivalence relations organize the set on which they are defined into subsets of related elements called equivalence classes.
In the case of
C-equivalent points, if X t S, then the equivalence
of x, denoted
class
[X] is
[x]
= {y E 5
I x ~ y}
= {y e S
| there exists g e C such that g ( x ) = y>
= (g(x) | g E C).
Since, in the case of C-quivalence, [X] is the set of images of X under C , [x] is called the orbit
of x under C and is designated orb^(x).
When
the number of points in orb^(x) equals #(C), then x is called a point of
general
position.
x is a point
Otherwise,
of
special
position.
When
x
is a point of special position, there exists one or more nonidentity elements g t C such that g ( x ) = x.
Let D denote a basis of S, x be an
element of S and C be a point group.
Then we define
o r b C ) D ( [ x ] D ) = {[g(x)]D
| g E C) .
(E4.34) Example - T h e symmetry of H4SiO,, is 4: of HtSiO,,, are given in Table 1.1. to C
The atomic coordinates
Show that the coordinates with respect
of the oxygen atoms designated Oi, 0 2 , 0 3 and 0» are mapped into
self-coincidence by the matrix representations of the monaxial group 4 where M c ( 4 ) = {M c (1), M c ( 4 ) , M c ( 2 ) , M c ( 4 " 1 ) } .
That is, the four oxygen atoms of the molecule are 4-equivalent.
Solution:
This will be done by showing that 0j is 4-equivalent to each
of 0 2 , 0 3 , and 0».
Since the coordinates of the vector r emanating from
the origin to 0j given in Table 1.1 are
[r] c = [1.281, 0.466, 0.877] t
,
and since
Mc(1)[r]c =
"l
0
0
"l 281
0
1
0
0 466
0
0
1
0 877
146
"l 281 =
0 466 0 877
Mc(4)[r]c =
' 0
1
0
"l 281
-1
0
0
0 466
0
0
-1
0 877
-1
0
0
1 281
0
-1
0
0 466
0
0
1
0 877
Mc(2)[r]c =
Mc(4"1)[r]c =
0.466' -1.281
=
-0.877 -1.281" -0.466
=
0.877
0
-1
o'
"l 281"
1
0
0
0 466
0
0
-1
0 877
"-0 466" 1 281
=
- 0 877
we see that the orbit of r is orb ?
c
(r)
= {Mc(o)[r]c
| « £ 4)
= {Mc(1)[r]c, Mc(4)[r]c, Mc(2)[r]c>
But these
Mc(4"1)[r]c>
"l 281
" 0 466"
- 1 281
0 466
- 1 281
- 0 466
1 281
0 877
- 0 877
0 877
-0 877
>
are the coordinates
of Oi, 0 2 )
03
^-equivalent to each of the other oxygen atoms.
- 0 466"
and 0,,.
Hence Oj is
The reader should repeat
this process for each of the remaining oxygens in the molecule and observe that a similar result is obtained. (P4.11) Problem:
•
Show that the set of hydrogen atoms designated H 1 } H 2 ,
H 3 and H 4 in H^SiO« is mapped into self-coincidence by the elements of M^C^)-
Do this by forming the orbit of [rj^, where [r]^ is triple of
the coordinates of one of the hydrogen atoms in Table 1.1. (P4.12)
Problem:
Show that the silicon atom in H»SiOi, is on a point of
special position and that its orbit consists of a single point. (E4.35) Example:
Show that the faces on the crystal in Figure 4.3 are 147
Figure 4.3: A set of faces comprising a trigonal dipyramid that are i-equivalent to (321).
mapped into self-coincidence by the isometries of the monaxial group 6. The natural basis earlier for 6.
for the crystal is the basis P = {a,b,c} described "ii ~v ?v
Recall that the face poles s = ha
crystal are defined in terms of its basis P . that
Solution:
+ kb
+ He
of a
In Appendix 3 it is shown
-t M p *(a) = M p (a) This problem will be solved by showing that the image under
6 of each face pole of the crystal is another of its face poles.
That
is, if [S]p* represents a face pole, then we must show that M p *(cO[s] p * also represents a face pole for each a t 6. face pole [s]p* = (327)
For example, consider the
and note that 1
Mp*(1)[»]p* =
o
0 0
1 0
2
1
1
0
0 M p *(6)[s] p *
-1
0
1
0
0-1
-1
-1
0
1 0 0
M p *(m)[s] p * =
2
=
1 0
-1
M p *(3)[S] p *
3
o' "3
0 0
1
"l
0
o'
3
0
1
0
2
0
0
-1
1
148
3 =
2 -1_
Figure 4.4:
A dioptase crystal with a (110) face
of a hexagonal prism labelled (o), and (021) and (131) faces
of
rhombohedra
labelled
5
and
X,
respectively.
,-1 Mp*(3 ')[»]p*
o
1
o
-1
-1
0
0
1
0
MpM^'lIslp* =
-1
-1
0
1
0
0
0
0 - 1
When these triples are collected together into a set, we have the orbit of face poles that are 6-equivalent to (321):
=
{M p *(a)
| a e
6
}
This collection of equivalent faces is called a crystal face form and is designated by placing the indices (hkl) of the representative plane of the orbit between braces, {hkl}. class
Thus, {321} denotes the
equivalence
of faces on the crystal in Figure 4.3 that are 6-equivalent to
(321).
• 149
(P4.13)
Problem:
Figure 4.4 is a drawing of an idealized
crystal
of
dioptase, CuSi0 3 *H 2 0, showing a (110) face of an hexagonal prism labelled
a and (021) and (131) faces of rhombohedra labelled s and x,
respectively.
Assuming that the point symmetry of the dioptase crystal is 3, find the indices
of each of the faces on the crystal that are 3-equivalent to
(110), (021) and (131).
Then assign indices to each of the 3-equivalent
faces on the crystal. Table 4.3:
Coordinates of the atoms comprising an SiO,,
group in narsarsukite (Peacor and B u e r g e r ,
Atom
X
1962).
z
y 0 3085
Si
0 0118
0,
- 0 0400
0 3024
0
0,
0 0488
0 1754
0 2684
0s
0 1324
0 4023
0 1934
0«
- 0 0977
0 3676
0 3062
(P4.14) Problem:
0 1921
The symmetry of the atoms about the origin chosen for
narsarsukite (a = b = 10.727A, c = 7.948A, a = 3 = TS = 90°) is
U/m.
(1) Determine the elements of M p ^ / m ) and the coordinates of the atoms in narsarsukite that are 4/m-equivalent to those in Table 4.3. (2) With atomic coordinates obtained in (1), prepare a drawing of the atoms in narsarsukite that are 4/m-equivalent to those in Table 4.3 viewed down the Z-axis. (3) Calculate the SiO bond lengths and the OSiO angles for the SiO* group described in Table 4.3.
Then calculate the bond lengths and angles
for an SiO» group that is the image under 4 of the one described in the table and observe that the geometries of the two are identical, demonstrating that 4 is an isometry. (P4.15)
Problem:
presented
on
the
Stereoscopic drawings of C-equivalent ellipsoids are next
four
pages
crystallographic point groups G .
for
each
of
the
13
monaxial
Examine these drawings in Figure 4.5
and confirm their point symmetries. 150
F i g u r a 4 . 5 (on this a n d tha following p a g a * ) : Stereoscopic pair plots of C-equivalent ellipsoids for each of the 13 monaxial crystallographic point groups G.
1
2
152
V] 4/m
4 /
6/m
\i
\i "Ì
m
154
4
6
155
CHAPTER
5
THE POLYAXIAL CRYSTALLOGRAPHIC
"Much
of
the
symmetry.
importance
Just
as
of measurement
numbers
has
metry.
With each
terizes
the symmetry
of
been figure
groups can
be
chosen'),
comes used
groups
w e associate
of the figure."
POINT
from
their
to measure can
GROUPS
connection size
be used
a group,
and
this
with
(once a
to measure group
unit sym-
charac-
-- J. R. Durbin
INTRODUCTION
In Chapter 4 we derived all of the possible monaxial crystallographic In this chapter we shall learn how all of the
possible
proper polyaxial point groups are constructed from the proper
point groups.
monaxial
point groups. (T4.28),
we
Then, using the Improper Point Group Generating Theorem shall
derive
all
crystallographic point groups.
of
the
possible
improper
polyaxial
The interaxial angles between the rota-
tion axes of the rotations participating in any one of these groups are then determined.
As in Chapter 4, a special basis P will be chosen for
each point group.
PROPER
( D 5 . 1 ) Definition:
POLYAXIAL POINT
GROUPS
Let C denote a proper point group.
If C has more
than one axis associated with its nonidentity rotations, then we call C a proper
polyaxial
group.
In our investigation of the polyaxial groups, we will be examining combinations of monaxial groups.
The task of finding the possible proper
polyaxial point groups will be considerably more difficult than that of finding the monaxial point groups.
Our first goal is to establish the
inequality which will state that three monaxial groups associated
with
nonequivalent pole points with orders Vi, v 2 and v 3 , respectively, can be used to form a proper polyaxial point group only if
1/Vi + l/v2 + l/v3 > 1
157
.
Figure 5.1: 322
The set of all pole points belonging to the nonidentity rotations of group
(see Figure 3.13 for a drawing of rotation axes of the group).
The basis vectors a ,
b and c coincide with the coordinate axes X , Y and 1, respectively, where ct = B = 90° and 1 = 120°. those in in [OlOJj
To
The nonidentity rotations in 3 leave the antipodal points p ! 1 and p 1 2 2 leave p 2 i leave
paj
and p ) 2
fixed, those in
fixed,
leave p , 2 and p 2 2 fixed and those
fixed.
and
facilitate our proof that will establish this inequality, we shall
consider the surface B of a unit ball centered at 0. Any point isometry a acting on B maps B onto itself.
In fact, a is completely determined
by its action on B because the effect of a on B determines the images {a(i) ,a(j) ,a(k)}, where C = {¡,j,k} is a cartesian basis, which in turn completely determines a.
A nonidentity proper rotation h about the ro-
tation axis t leaves exactly two antipodal points on B unmoved.
These
points are precisely the points, on opposite sides of the ball, at which i and B intersect and are called the pole points belonging to h.
If these
two points are labelled p and q, then they are the only points x on B that satisfy the equality /?(X) = x. The set of all pole points belonging to the nonidentity rotations in C will be denoted by P(C) and will be called the set of pole points belonging to C. is an equivalence relation on P(C).
Note that C-equivalence
Applying C-equivalence to P(C),
we partition P(C) into its set of equivalence classes.
For example, the
pole points of 322 P{322)
=
{Pll,Pl2,P21>Pl2>P23>P31>Pl2>P33}
158
are denoted in Figure 5.1 by p.. class p..
where / indicates to which equivalence
We denote the ith
belongs.
belonging to C by
equivalence class of pole
points
C.(C).
( E 5 . 2 ) Example - The 322-equivalence class of p class under 322-equivalence of p
u
:
Find the equivalence
shown in Figure 5.1.
u
That is, find
0^322).
Solution:
By definition of an equivalence class,
[p 11 ] = { q E PCC)
I
P l l
~ q}
.
By definition of 322-equivalence, [Pu]
= { q e P(322) = ig(Pii)
=
| there exists g e 322 such that g ( P n ) = q }
I 9 e 322}
i1(Pxx).3(pll),3-1(pM),I1«>]2Cp11),I01012(p11),I110l2(pll)>
= {Pii.Pizl Hence Ct(322) (P5.1)
=
Problem:
(P3i>P32>P33)
as
{p„,p
n
) Cz(322)
Verify that
=
{p2j,p22,p23}
and
C3(322)
=
shown in Figure 5.1.
Note that {C1 (322) ,C 2 (322), P(322)
= Cx(322)
C3 (322)} partitions P(322). U C2(322)
U
That is
C,(322)
and C.(322) where 0 is the empty set.
n
C .(322)
= 0 when /' / /
,
Note that # ( C 1 ( 5 2 2 ) ) = 2, #(CZ(322))
= 3 and
# ( C 3 ( 3 2 2 ) ) = 3. ( P 5 . 2 ) Problem:
Draw a diagram showing the rotation axes of 422.
P!! denote a pole point of
p 2 1 a pole point of
159
Let
and p 3 1 a pole
point of
Find ^ ( 4 2 2 ) ,
C2(422)
and C 3 (022).
Note that every
pole point of 022 is in one of these equivalence classes.
Now w e shall turn our attention to polyaxial rotation groups G
and
the subgroups of C associated with its pole points.
(D5.3)
Definition:
Let p denote a pole point belonging to C .
collection of all rotations of C that have p the stabilizer
as a pole point
of p in C and is denoted by C p .
C
= {g e C
p
Then the is called
That is
| g ( p ) = p}
.
The stabilizer of a pole point p., is denoted by C...
(T5.4) T h e o r e m :
Let p denote a pole point of C .
Then C ^ is a subgroup
of C .
Proof:
Since G
9i> 92 e G
•
is finite, we need only show that C ^
is closed.
Let
Then
9i9i(P) = 9i(92(P)) = 9l(P) = P Since g i g 2 ( P ) = P and g i g 2 nonempty, C p
E C
(C is closed) g i g 2 e C p .
Since
is
is a subgroup.
Since the rotations of
c
leave p fixed, they all have the line I
containing 0 and p as their rotation axis.
Consequently, C p is a proper
monaxial group and therefore isomorphic to one of the cyclic groups listed in Table 4.2. In the case of
and
322,
(322) 2 1
=
(322) 3 2 =
(322), x
=
(322) 2 ,
(322)„
=
(322) 3 , =
J
(322) X 1
=
(322) 1 2 =
{3,3-1,1}
=
(HOOl^j {[iio]2>1}
0 1 0
^,!}
We observe in this example that two pole points are associated w i t h each
160
monaxial group (Figure 5.1).
It is also evident that the pole
p 21 j p 2 2 , p 2 3 j P3i, p 3 2 j and p J 3
where the rotation axes have different orientations. points p
n
points
are each associated with the group 2 The remaining pole
and p l 2 are similarly associated with group 3.
( T 5 . 5 ) Theorem:
Let C denote a proper crystallographic point
Let p denote a pole point and let q be G-equivalent to p .
group.
Then C ^ is
isomorphic to C ^ and hence they are both isomorphic to the same proper monaxial point group of Table 4.2. Proof:
Since q is C-equivalent to p , there exists a rotation g E G such
that g ( p ) = q. g
1
0;
(q) = p and so g h g \ q )
all h £ C p . an
Consider
C p •+ C q defined by 8 ( h ) = g h g 1 . = g h ( p ) = g ( p ) = q.
By EA8.5, 8 is an isomorphism.
Note that
Hence 8 ( h ) e C q for
Since isomorphism defines
equivalence relation, C ^ and C ^ are isomorphic to the same proper
monaxial point group of Table 4.2.
( E 5 . 6 ) Example:
Solution:
e
Show that (322)22 = { 3 h 3 _ 1
| h E (322) 21 ).
As shown above
(322)21
=
(522)22
=
[ ^ ^ { l . t
1 0 0
^ }
and [07°]2={1,[010]2) .
Then {3h3_1
| h E (322)21)
=
{313" 1 . S ^ 1 0 0 ^ " 1 }
=
{1,
= (P5.3) Problem:
[010]
(322)22
2}
Confirm the results in E5.6 with matrices showing that
M 0 ((322) 2 Z ) = { M D ( 3 ) M D ( h ) M D ( 3 " 1 ) Note that since M^(3 for MQ((322)21)
D
•
1
) = M^(3)
| h E (322) 21 )
the matrices described in P5.3
are similar (see Appendix 7) to the matrices in
161
.
(322)22). equivalence
Hence while p 2 i relation
of
and p 2 2
D4.32,
the
are 322-equivalent under the
matrices
in
(322) 2 1)
and
M^((322) 2 2) are equivalent under the equivalence relation of DA3.3 (see also EA7.4).
A relation corresponding to similarity can be defined on
the subgroups of G. (T5.7) Theorem:
This relation is called
Let C denote a group.
conjugation.
The relation defined on the set
of subgroups of C defined by
Hi ~ H 2 where H x
and H 2
relation
~
conjugate
to H 2 .
there exists a g E C such that g ^ g
^ = H2
,
are subgroups of C , is an equivalence relation. The
is called conjugation
and if Hi ~ H2,
H¡, is said to be
The proof of T5.7 is essentially the same as that of EA7.4 where we demonstrated
that
similarity
of matrices
is an equivalence relation.
Conjugation and C-equivalence are very closely related concepts.
Con-
sider T
| p e P(G)}
= {Cp
.
Conjugation is an equivalence relation on T while C-equivalence is an equivalence relation on P(C). p ~ q
Furthermore, we have «-»• C p ~ C q
where C-equivalence is used on the left and conjugation on the
right.
Consequently, if p is a pole point, then an isomorphic image of C ^ occurs about any axis having g(p) as a pole point for each g E G.
Suppose we
have located the position of the axis of one of the rotations of G.
Then
we can find others by mapping the axis under the operations of G.
Fur-
thermore, the axes found in this manner will be associated with cyclic groups of the same order as the original axis.
This observation will be
extremely important in our construction of the rotation groups.
(L5.8) Lemma:
Let C denote a proper point group such that #(G) > 1.
Then 2(/V - 1) =
t I
".(v. - 1)
/'=1 162
where N = #(G), t is the number of equivalence classes of pole points, n. = #(C.(C)) and v. = Proof:
iKC..).
The basic strategy for establishing this theorem will be to find
two distinct ways of counting the nonidentity rotations of C. will be two expressions each equaling twice the number of rotations of C.
The result nonidentity
This will establish the result since these two equal
expressions will be precisely those appearing in the equation. by taking each pole point p.. in
P(C)
We begin
one at a time and counting the
number of nonidentity rotations of C leaving p.. fixed.
The sum of these
numbers taken over all the pole points in P(C) will equal twice the number of nonidentity
rotations
in C because each of these rotations leaves
exactly two pole points fixed and hence is counted twice.
The number of
nonidentity rotations leaving p.. fixed is if(C..) - 1 = v. — 1. Thus, for the pole points in C.(C) we have ¿((nonidentity rotations leaving p.
fixed) = v. — 1
\
#(nonidentity rotations leaving p.^ fixed) = v. — 1
I \
//(nonidentity rotations leaving p.
fixed) = v. - 1
Summing up these numbers we find that the contribution n. (\>. - 1) for each 1 < i < t.
n. equations
from
C.(C)
is
Adding the contribution from each of the
t equivalence classes, we find that the sum is
t Z n.(v. - 1). /=1
Since
N - 1 is the number of nonidentity rotations in C, it follows that twice the number of nonidentity rotations in C is 2{N - 1) and so we have established that t I
2(/V - 1) =
n.(v. - 1)
.
•
/=1 From
E5.2
#(C2 (322)) =
3
and
P5.1,
we
see
that
nx =
and
n3 =
#(C 3 (322)) = 3.
#(C t (322)) = 2 ,
Also
Vl
n2 =
= 1K3) = 3, v 2 =
# ( [ 7 0 0 ] 2 ) = 2 and v 3 = #( i 7 7 ° ! 2) = 2. Since N = #(.322) = 6, we can verify L5.8 in this case by observing that 2(6 - 1) = 2(3 - 1) + 3(2 - 1) + 3(2 - 1) 163
.
(P5.4)
Problem:
Using the information you have developed
about
422
(including the solution to P5.2) verify the equation in L5.8 for 422. (T5.9)
Theorem:
Let p and q denote C-equivalent pole points and let
T denote the set of all elements of G that map p to q.
Then T is a left
coset of G .
P
Proof:
A discussion of cosets and related topics can be found in Appendix
Since p is C-equivalent to q ,
7.
there exists g E C such that g ( p ) Let t E T.
We shall show that T = 9 C p .
q.
t ( p ) = q.
=
By definition of T ,
Since g ( p ) = q , we have
g_1t(p)
Hence g ' t E C
Conversely, suppose h E gC
Therefore t E g C
Then h = g k where k E C
(q)
g
p
Hence
gk(p)
h(p)
g(p) q
Hence h E T.
c
Consequently T = g^p-
One consequence of T5.9 is that if G is a finite proper point group such that #(C) > 1 and p is a pole point of G, then there is a one-to-one correspondence between the cosets of
and the pole points that are
C-equivalent to p .
then n,,
Hence, if p £ C.(C),
be the number of pole points in C .(C) C p in C .
which is defined to
, equals the number of cosets of
Recall (see the proof of TA7.13) that each coset of C ^ has
the same number of elements as does C
, that is v. elements. P' '
Since the
cosets of C p partition C into n. cosets each having \>. elements we have established that
#(C) In the case of 322, v
i
=
3 >
v
2
=
v
3
= 2
N = n.v, for each 1 < i < t i i
(5.
we observe that since /7j = 2, n 2 = n 3 = 3 and
and that N = 6
n.v. in all three cases. ; /
164
(P5.5)
Problem:
Show that n.v. = N
for each 1 < / < 3 in the case
of
422.
(T5.10) Theorem:
Let f denote the number of equivalence classes of pole
points of a finite proper point group C where N = # ( G ) > 1.
Then t = 2
or 3 and (1)
if t = 2, C is a monaxial group and
(2)
if t = 3, C
is a polyaxial group such that
1/vi + l/v 2 + 1/v3 > 1 and # ( C ) = 2/(1/vi + l/v 2 + l/v3 - 1) Proof:
.
By L5.8, we have
2(N - 1) =
and by (5.1), we have /V = n.v..
I n (v. - 1) ;=1
.
(5.2)
Dividing the left side of
(5.2) by N
n v
and the right side of (5.2) by j j> we obtain
2 - Z/N =
t I (1 - 1/v.) /=1
.
(5.3)
Since v. is the order of the stabilizer of a pole point, v. > 2. t t I (1 - (1/v.)) ^ Z (1 - i ) /=1 /'= 1
=
t I (i) = t/2 /'=1
Hence
.
Also, since N S 2, 2 > 2 - 2//V
.
Hence, from (5.3) 2 > t/2
Hence 4 > t.
.
Therefore, t can only equal 1, 2 or 3.
We can thus conclude
that there are no rotation groups having more than 3 equivalence classes of pole points.
We now examine each of these three cases for the value
of t. C a s e w h e r e t = 1:
2 - 2/N =
In this case, Equation (5.3) becomes t 1 I (1 - 1/v.) = Z (1 - 1/v,) /'=1 /=1 165
or 1 - 2/N
The
=
1/vi
left member of this equation is always nonnegative because N ^ 2,
but the right member is always negative because Vj > 2, which is a conTherefore, t cannot equal 1, from which we conclude that
tradiction.
P ( C ) must contain more than one equivalence class of pole points.
Case where t = 2:
In this case Equation (5.3) becomes
2 2 - 2/N =
I (1 - 1/v.) = (1 - 1 / v O + (1 - l/v 2 ) /=1
.
By a little algebraic manipultion we find that
2 = A//V! + /V/v2
.
From Equation (5.1) we have that N/\>. = n., and so the above expression simplifies to 2 = n1
Because n^
and n 2
+ n2
are positive integers, we conclude that n ± = n2
is the only possible solution.
- 1
Hence, for a rotation group with t = 2,
we have two equivalence classes consisting of one pole point each.
Al-
together C has a total of two pole points, which defines one and only one rotation axis. of
Therefore, those groups with two equivalence classes
pole points must be the proper monaxial groups given in Table 4.2.
The number of elements in each of these possible monaxial groups is equal to the order of the rotation axis, # ( G ) = Vj = v 2 •
Case whe r© t — 31
In this case Equation (5.3) expands to
2 - 2/N = (1 - 1/v,) + (1 - l/v 2 ) + (1 - 1/v,)
.
Rewriting this result we see that
1 + 2/N = 1 / v i + 1 / v2 + 1/v,
Since N > 2, it follows that 1 + 2/N
> 1 and so
166
.
(5.
#(C,(C)) =
1,KC,(C))
N/Vi
groups.
#(C,(C))
Group Name
c
N
#(C) =
C - vlv2vj
II
Symbol for
Possible finite proper polyaxial point
11
6. The group 332
is usually designated by 23 and the group 532
designated by
l/Vj
S o l v i n g for N
+
l/v2
+
l/v3
>
1
.
in (5.4) we o b t a i n
#(C) =
Us ing part Vj > v 2 S v 3 ,
is usually
235.
we
N =
2/ (1/v! + l/v 2 + l/v 3 - 1)
(2) of T5.10 w h e r e , shall
polyaxial point groups.
construct
for
all
Note that if
.
convenience,
of
the
we
possible
assume finite
> 2, then e a c h of the
that proper
fractions
1/v. w o u l d be less t h a n or equal to 1/3 for each i and so (5.5) w o u l d not be satisfied. or
equal
to
v 2 = 2 or 3. (5.5). groups
H e n c e v 3 = 2. -J and so
If v 2
> 3, then
(5.5) w o u l d
Suppose v 2 = v 3 = 2.
T h e s e groups, denoted n22
1/vi + l/v 2
again not be satisfied.
is
less
than
Therefore,
T h e n any value of Vj > 1 w o u l d satisfy w h e n n = Vj,
of w h i c h t h e r e are an infinite number.
#{n22)
= In
are c a l l e d the
.
If v 2 = 3 and v 3 = 2, then if v t > 5, (5.5) w o u l d not be satisfied. the only groups of this type are 332,
432
dihedral
Using (T5.10) w e see that
and 532.
finite proper point groups are r e c o r d e d T a b l e 5.1.
Hence
A l l of t h e s e p o s s i b l e N o t e that w e h a v e
The orientation of the three mutually
Figure 5 . 2 :
dicular 2-fold axes in 222 ordinate ^ ^ 2
system
with
along b .
2
perpen
These axes define a natural co-
lying
along c
Each 2-fold axis
[ 100]2
aiong
a and
is represented by a
diad
symbol.
Figure 5 . 3 :
Multiplication table f o r
Hp(222)
Mp(l)
Mp(1)
Mp(2)
Mp(2)
V
[10
°>2)
Mp([°10]2)
10
M„(I °]2, V
[010]
2)
Mp(222).
Mp(2)
V[100]2)
Mp([°10l2)
Mp(2)
V(,00)2>
V[010]2)
Mp(l)
v[010]2>
M„CI,00I2)
V
[010]
V
[100]
Mp(2)
2) 2)
Mp(2)
Mp(1)
yet to show that each of these possibilities actually occurs as a point group. CONSTRUCTION OF THE DIHEDRAL GROUPS In Appendix 6 we proved, for
r>22,
that the n-fold axis is perpen-
dicular to each 2-fold symmetry axis and adjacent 2-fold axes group must intersect at an angle of 180/n (TA6.1).
in this
To confirm that each
n22 is actually a group, we shall define a basis of S for each, write the elements of
r>22
as described in TA6.1 with respect to this basis and
then form the multiplication table to check closure. The construction of 222:
Since the 2-fold axes are mutually perpendic-
ular, we define P = { a , b , c } to be a basis where a, b and c are also mutually perpendicular such that each lies along an axis (see Figure 5.2). Hence the metrical matrix G for P is 168
G
g ii
0
0
0
g 22
0
0
0
g 33
=
[100] With respect to this choice of basis, the half-turns are denoted 2, [010] 2, 2 along a, b , C, respectively. By Table 5.1, 222 can only have 4 elements and so we conjecture that 222 = {1 ) 2 ) is a group.
[ioo] 2 ) [ oio] 2 }
The matrix representation of each of these can be found era-
ploying the approach used for 322 in Chapter 3. Mp(222)
Hence
= {Mp(1),Mp(2),MpC[100]2),Mp([010]2)}
.
To confirm that 222
These matrices are described in Table 5.2.
is
a
group, we form the multiplication table of Mp(222) shown in Figure 5.3. Since no new entries resulted in the formation of the table, Mp(222) is closed under matrix multiplication and, since it is finite, it is a group. Since the mapping from Mp(222) to 222 that maps Mp(ot) to a for each a preserves the operation, the multiplication table of 222 under composition can be obtained by deleting the Mp(
) for each element (Figure 4.2).
Hence, 222 is a group. T h e construction of 322:
As in Chapter 3 (see Figure 3.10), we choose
P = {a,b,c} where C coincides with the 3-fold axis, a coincides with one of the two-fold axes and b = 3 ( a ) (Figure 5.4).
Hence the metrical matrix
G of P is 9
G =
il
-g
n/2
o
-g n/2
g w
0
o
o
g 33
Since 60 = 180/3, there are two-fold axes at 60° intervals starting with the one coinciding with a.
Hence, a two-fold axis lies along b.
Recall
that this is the same basis that was used for the monaxial groups 3, 3, 6, 6 and 6/m.
With respect to P, 169
Table 5 . 2 :
T h e nonzero e n t r i e s of the matrix r e p r e s e n t a t i o n s M ^ ( a ) f o r
rotation isometries o g r o u p s 1, 2, 4, 222, 422, 23 a n d 432 f o r P -
(a,b,c).
Mp(1) : In= «22 = t,, = 1
«22 = 1; «11 = «12 -1 =
Mp(2) : I,,= ii2 = -l; in = l
= -1 : «12 - 1; «21 = «12
V
[010I
2)
Mp([101]2)
»n = i; in = «n = -i
M / " 1 ^ ) : «21 = i; »12 ' «11 = -1
in = i; tn = in = -i
M/^V
«n = «n = l; in =-1
M / " 1 ^ ) : «ii~ i; «12 = «21
1
) • »12 = i; «11
=
«21= -1 -1
[ l] 1 = -1 i.j = ti. = i; t.i = -l Mp( " 3- ) : «11 = 1; «21 = «12
V
ti01]
Mp(
2)
[0il]
2)
V[110]2) V
ni0]
2)
V [ 1 1 1 ]3)
in = in = in = -l
Mp(4) : «ai =«.. = l; «12 = -1
«11 = In = «21 = -l
Hp(4"1) : «12= «ii = l; «21 = -l
«21 = «12 = 1; «1. = -1
V
1
=
&X2
=
=
[100]
= = 4 ) = «11 " «12 i; «21 -1
v 1 1 0 0 1 «- 1 )
:
«ii = «21
=
«21 = «12 = «11 = 1
Mp(I01014) :«22
: «11 = «12 = «21 = 1
V 1 0 1 0 1 « - 1 ) '• «ii ~ «22
=
i; «12= -1
In ~ 1; «11 -1 =
= -1 i; «11
522 = {1,3,3-1,I100]2 [110]2 [010]2} In Figures 322,
3.14 and 3.15, the multiplication tables for M^j(522) and
respectively, are displayed.
From these tables, we observed that
322 is a group. The construction of 422:
As in Chapter 4, we choose P = { a , b , c } where
c coincides with the 4-fold axis, a 4(a).
is along a 2-fold axis and b =
The metrical matrix G for P is
011 G =
0 0
0
0
Sii
0
0
Su
Since 45 = 180/4, there are two-fold axes at 45° intervals starting with the one coinciding with a.
Hence, there is a two-fold axis along b .
The elements of 422 with respect to P, 5.5) 170
given in P3.14 are (see Figure
Table 5.3:
N o n - z e r o e n t r i e s of t h e m a t r i x r e p r e s e n t a t i o n s M ^ ( a ) a n d
Mp*(a)
f o r t h e r o t a t i o n ¡sometries a of p o i n t g r o u p s 3 , 6 , 3 2 2 , a n d 622 f o r P = {a,b,c} a n d P* = {a*,b*,c*>. MpC«)
Hp(l) : t n = «22 = «3 3 = 1
V
[ 0 1 0 1
2)
: i22 = 1; 1.1 = «21 =
Mp(2) : i n = 1 2 2 = - 1 ; i 3 3 = 1
V
[ 1 1 0 ]
2)
: «21 = i,2 = ill = - 1
V
[ 1 0 0 ]
Mp([
21
2,
in
= i; «12 = i 2 2 = «33 = - 1
Mp(3)
°]2)
in
= in
= l; i 2 2 = «33 = "I
Mp(3_1)
= i; l „
Hp(6)
«21 = i n M^C[120]2>
i12
=
i2 2
=
= "I
: t2, = l „
= 1; t 1 2 = l 2 2 = - 1
: i, 2 = t,, = 1; I,, = i 2 , = - 1
: 1,, = t 2 , =
Mp(6_1)
1; ill = «33 = "I
= -1
: tn
= 1; «i 2 = - 1
= til = «33 = 1; «21 = - 1
Mp-(a)
(1) : t,i = «22 = tjj = 1
[010] 2) Hp' (
: i22 = 1 ;
Hp* (2) : «,, = «22 = - 1 ; «i. = 1
[1l0] 2) Hp- (
: t2i = « . 2
v
v
Hp*
Mp*
Hp*
([100]2)
([210]2)
([110]2)
([120]2)
: «1, = 1; «21 = «22
=
«13 = "I
Hp- (3) : l 2 , = i „
l„
= i, 2 = «3. = - 1
=
= 1; I,, = «i 2 = -1
: «11 = «12 = 1; «22 = «33 = -1
1 Hp" (3" ) : l l 2 = I,, = 1; t 2 , = «22 = - 1
: 12, = 1 „
Hp- (6) : i 2 1 = H 2 2 = I,, = 1; l 1 2 = -1
= 1; «33 = "I
: «21 = «21 = l; «11 = «3 3 = - 1
Figure
1 Hp- (6" ) : I,, = l,i = t „
5.4:
= 1; «1, = - 1
The orientat ion of the rotation axes in
322.
The 3-fold axis of the group is perpendicular to a plane of three
2-fold
axes
with
adjacent
intersecting at an angle of 60°.
2-fold axes in the plane The basis vector C is de-
fined to lie along the 3-fold axis, a is defined to lie along one of the 2-fold axes and b is defined to lie along another at
120°
so that b = 3(a).
parallels a, ^ ^ ^
Thus, 3 parallels c,
parallels a + b and
parallels
b.
The 3-fold axis is represented by a triad and each 2-fold by a diad svmbol.
171
Figure
5.5
The
orientât ion of the rotation axes
The 4-fold axis of the group is perpendicular four
2-fold
axes
with
intersecting at 45°.
adjacent
2-fold
in 422.
to a plane
axes
in
the
of
plane
The basis vector a is defined to
lie
along one of the 2-folds and b is defined to lie along another at 90° to a so that b = 4(a). and
1
2 are disposed as
j [110]-/
and
n
.
parallels - a
b.
Thus, 4 parallels c,
in 222,
'2
parallels
a + b
The 4-fold axis is represented
by a tetrad and each 2-fold by a diad symbol.
Figure 5.6: 622.
The orientation of the rotation axes of group
The 6-fold axis
is perpendicular
2-fold axes w i t h adjacent at 30°.
2-folds
to
a
plane
in the plane
of
six
intersecting
The vector C is defined to lie along the 6-fold axes,
a is defined to lie along one of the 2-folds and b is defined at 120° to a so that b = 3(a). Hence, 6 parallels [100].2, 1/ H O '2 /. . [010J. . . ,,, . /270/J. c, 1 and 1 '2 are disposed as in 322 and 1 '2
— | — y
as in 322
parallels 2a + b , lels - a + b .
l120h
parallels a + 2 b
and
l11°h
w
a
paral-
The 6-fold axis is represented by a hexad and
the 2-folds by diad symbols.
The multiplication table for M p ( 4 2 2 ) and (422) were found in P3.15.
An
examination of the multiplication table of 422 shows that 422 is closed under composition and hence is a group. T h e construction of 622:
We choose the basis used for 322 for 622.
Since
30 = 180/6, there are two-fold axes at intervals of 30° starting with the one
coinciding with a.
elements of 622
622 =
Thus, there is a two-fold axis along b.
The
(see Figure 5.6) are
{1,6,3,2,a'Ve"1,^100^,
(P5.6) Problem:
Find all of the matrices in Hp(622).
Confirm your re-
sults with those given in Table 5.3.
(P5.7)
Problem:
that Mp(622)
Prepare a multiplication table for Mp(622) and observe
is closed under multiplication, demonstrating that 622 172
is
a group.
(P5.8) Problem:
For 522 no basis exists that gives all of the pole points
and matrices with integer entries. where k axes.
Therefore, a cartesian basis is used
is along the five-fold axis and i is along one of the two-fold Find the matrices in M£.(522) and form the multiplication
table
showing that M^(522) is closed and hence 522 is a group.
Note that 522 is not a crystallographic group and hence does not map a lattice into self-coincidence.
This is why no basis can be found such
that the representation of the pole points and the matrices of the mappings consist entirely of integers. crystallographic point groups. all of this type.
This fact
is
true
for
all
non-
In particular, n22 groups with n > 6 are
However, using a cartesian basis as in P5.8, each of
these can be shown to be groups. C O N S T R U C T I O N OF T H E C U B I C A X I A L
GROUPS
In the construction of these groups we shall need to map pole points using the matrix representation of the constituent rotations.
Since the
pole points are constrained to be on a unit ball, the triple representing a given pole point can be somewhat complicated. [/3/3,/3/3,/3/3]t.
the pole point
For example, consider
As this pole point lies on the zone
[111], we shall use [111]1" to represent the pole point to simplify the computations.
We shall see that each pole can be easily represented in
this manner.
(E5.11) of
222,
Example: form
the
Using the zone symbols to represent the pole points equivalence
classes
of
pole points with respect to
222-equivalence.
Solution: points.
Since 222 has three 2-fold rotation axes,
it
has
six
pole
Recall that by the way the basis P = { a , b , c } for 222 was defined,
the triples for these pole points on the unit ball B are
{a/a,-a/a,b/b,-b/b ,c/c,-c/c}
.
The representatives formed from the zone symbol associated with these pole 173
points are {[a]p,[-a]p,[b]p,[-b]p,[c]p,[-c]p]}
=
{[100]t,[100]tJ[010]1,[010]t,[001]t,[001I1}
The
equivalence
{g(p)
class
| g t 222}.
of
a
given
Starting w i t h
pole
.
point
p
is
[a] p , the equivalence class
the
set
[a] of
a
is [a]
=
{Mp(g)[a]p
| g t
[b]
=
{[b]p,[-b] p )
[c]
=
{[c]p,[-c]p}
222}
= {[a]p,[-a]p}
.
Similarly,
and
This
.
is consistent with the information given in Table 5.1 w h e r e w e ob-
serve that the pole points of 222
are
partitioned
into
3
equivalence
classes with two pole points each.
(P5.9) 322,
Problem:
form
the
322-equivalence.
Construction
of
satisfied if 332
c
Using the zone symbols to represent the pole points of equivalence
classes
of
pole
points
with
respect
to
Confirm your answer by referring to Figure 5.1.
332(=23):
We
shall discover what conditions must be
is to be a group.
Once these conditions have been es-
tablished, we shall use them to determine the interaxial angles that must occur between the generating rotations it is a group.
and then construct 332
We begin by noting that if there
does
not
and show exist
two
third-turns whose composition is a half-turn, then the set of all third turns (recall that the inverse third-turn is a third-turn about the other end of the axis) together with the identity would be a closed set composition
which would violate part (2) of T5.10. in 332
under
and hence we would have a polyaxial group of the form
Hence, there exist two third-turns
whose composition is a half-turn.
In Appendix 6, we showed (PA6.2
and PA6.5) that when 33 = 2, then
• • • >9 n ) denote the generators of C. under C
If L is invariant
then it is invariant under each of {g^ .g^, . . . >9^) • N°w suppose
L is invariant under each of {g l ,g„, . . . ,g } . Let g t C. 205
Then
g is a
finite product
(composition)
}, say
g
Then
h 1 h 2 -. .hf where h(. £ { g ^ g ^ ... ,g n ). g(Z.) =
of
h 1 h 2 ...h f (Z.)
=
h 1 h 2 ...h f _
=
h ¿L)
=
L
^L)
.
•
Given a point isometry a and a lattice LQ we need a strategy for determining whether L ^ is left invariant under a or not.
Note that
a{LQ)
is the lattice generated by a(£>) = (a(a),a(b),a(c)} since a(L/a + vb + W C ) = t/a(a) + Va(b) + wa(c) Hence L^
= a ( L i f
and only if D and ot(D) generate the same lattice.
Using T6.1, to show that L ^ is left invariant under a, we need only show that each vector in D can be expressed as an
integral
combination
of
a(D) and vice versa. (T6.13) Theorem: a basis of S.
Let C denote a point group and let D = {a,b,c} denote
Then L^
is invariant under G if and only if M^(a) is an
integral matrix for each generator a of C. Proof:
Recall that
M 0 (cO
[a(a)]
D
[«(b)]D
[o(c)]D
which is the change of basis matrix from a(D) to D.
Since we know (see
CA3.8) that det(M_.(oO) = ±1, T6.3 yields the result that /.„ = /. if U U a\U) and only if M^(a) is integral. • (E6.14) Example - A lattice left invariant under a point group C: a and f5 are generators for some point group C,
206
Suppose
D = {a,b,C} denotes
a
basis for S and a(a) = b , a ( b ) = - a + c, a(c) = c, 3(a) = - b , 3(b) = - a , and 3(c) = -C. Solution:
Show that LQ
is invariant under G.
To show that the lattice L p is invariant under C , we must show
that M n (a) and M n (3) are both unimodular.
M D ( then T 2 = TJT * and p2 = 1 0 ! where T is the translation such
=
that t(p!(o 2 )) = o 2 . Proof:
Note that TPI(O2) = T ( P I ( o 2 ) ) = o2
and so TPJ is a point isometry.
Since T X T ' is a translation and iPt is
a point isometry such that a = (lit "*")(tPI), P2
=
,
and
TPJ.
Suppose the origin O is fixed and a is an isometry. there exists a unique P(o)
1
by T/.10, t 2 =
= o and a = TP.
the linear
component
with respect to O .
translation
D = {a,b,c}
and
point
isometry
We call t the translational
component
P such
that
of a and P
of a (since a point isometry is a linear mapping) Since a = TP, a(r)
where t = T ( o )
T
Then by T7. 10
=
t(P (r))
=
P(r) + t
.
is the translational vector for T.
is chosen.
NOW suppose a basis
Then P can be represented by the 3 x 3
matrix
M^j(P) and the translational vector t of T can be represented as the triple [t]p.
Creating a 4 x 4 matrix, denoted
= {M^(P) | [t]^}, from
these in the.following manner,
RN(A) = {MN(P)
MD(P)
| [t]D
0 0 0
I I
| [t]n} =
238
1
we
obtain a matrix representation for a.
In order to accomplish this
representation, we use 4-tuples, elements of R1*, to represent the vectors, r in S .
The 4-tuples are constructed by putting a dummy 1 in the
fourth position below [r]£j-
(E7.12) Example:
Verify that R^Ca) = {M^CP) | [t]^} represents a = iß
where t = t(o) in the sense that
[«(r)] D
" [r] D RD(a) 1
Solution:
Let "il MD(S)
=
i2l
^12
^13
^22
^2 3
£39
[t] D =
£33
tr] 0 =
Then fc 1 2
£ 13
tl"
X
12 1
^2 2
^2 3
tz
y
2-3
t. 1
_1
"Uli
[r] D { M D ( ß ) I [t]D' n}
=
1
d3 2
£3 3
0
0
0
« h *
+
Î12 y
+
1Î13Z
z
+
ti
12 iX + l22y + l22z + 12 i31x
+ n 3 2 y + 1"
t2
13 0
[t] D
MD(3)[r]D + 1
0
[t] D
[P(r)] D +
0
1
[fHr)] 0 + [t] D
1
[P(r) + t ] D
Kr)]
D (by (7.8)) •
In E7.12 we showed that the 4 x 4 a where a = xfi.
matrix given in (7.9) represents
The notation {M^(B) I [tj^}
(Seitz, 1935) for a with respect to o and
D.
(D7.13)
an
Definition:
Let
a =
if5 denote
is
called the Seitz
isometry
where
notation
t
is
the
translational component and 3 is the linear component of a with respect to
the
origin
O.
Let
{M^(3) I [ t (o) ] i s respect
to
Let
D
denote
a
basis.
called the 4 x 4
matrix
Then the matrix Rp(a) representation
of
a
= with
D.
O
denote
a choice of origin and D
isometries, then so is aTS and since
240
a basis.
If a and Z are
aï(r)
=
a(ï(r))
,
[r]D
[r]
R D ( a ï)
D
RD(a)|RD(ï)
Since matrix multiplication is associative, this equals
[r]
D
RD(a)RD(ï)
Hence R0(aï) = RD(a)RD(ï)
(7.10)
The composition aï can also be viewed in terms of the decomposition described in T7.9.
Suppose Ï = tiBi and a = T2fÎ2> then
(aï)(r)
Hence, a? = tf3 where 3
=
=
(T2MiPi)(r)
=
(TîPîtJCBiCr))
=
( t 2 e 2 ) ( M r ) + t i (o))
=
T 2 CB 2 CBiCr)) + P î d x C o ) ) )
=
B
2
M r ) + M t x C o ) ) + t2(o)
3 2 Bi and T is the translation whose translational
vector is P2(t1 Co)) + t 2 (o).
Therefore, in the Seitz notation, given an
origin o and a basis D,
R 0 ( a i ) = {M 2 M! I M 2 11 + t 2 }
,
(7.11)
where Mj = M p C M , M 2 = M ^ C M , t t = [Tjio)]^, t 2 = [t 2 (o)] 0 -
Note that
tt
R^(ai) =
and
t2
are
defined
here
to
be
vectors
in
R* .
Since
RD(a)RD(y),
{M 2
(P7.11) Problem: for any 3 x 3
I t 2 }{M! I t j = {M 2 Mi
I M2tx + t 2 }
.
Using matrix multiplication, confirm that (7.12) holds
matrices Mj and M 2 and any two vectors t x and t 2 in R3 .
241
(7.12)
Suppose that R
n(a)
=— {M ^LI | | t}. WJ . Then I IICII we W C can A N find I IIIU Rn(ot
by noting
that RpCa" 1 ) = (R^Ca))" 1 and observing that if R^Ca" 1 ) = {N | r} then
{M | t}{N | r} = {I3
I 0}
.
{MN I Mr + t} = {I3
I 0}
.
Hence, by (7.11)
Hence N = M
1
and r is such that Mr + t = 0.
That is,
r = -m'H Consequently, {M I t}"1 = {M" 1 I -M _ 1 t} (P7.12)
Problem:
Problem:
(7.13)
Use (7.11) to confirm (7.13) by showing that {M | t}{M _1
(P7.13)
.
| -M _ 1 t} = {I, | 0}
.
Show that {M I t)"1 = {M" 1 I -M _ 1 t}
by extending the procedure for calculating the inverse of a 3 x 3 matrix given in Appendix 2 to the 4 x 4 (T7.14)
Theorem:
case.
Let / denote the group of all isometries.
Then T is
a normal subgroup of /. Proof:
Let a E / and T E T.
According to the remark following DA7.11,
we need only show that ata ^ E T.
Using the Seitz notation with respect
to an origin O and a basis D, we can write R^j(a) = {M | tj} and Rpit) {I3
I t 2 }.
By (7.13), R^ia" 1 ) = {m" 1 | - m " 1 ^ } . R^axa"1)
=
{M | ^ > { 1 , | t j H M " 1 {M I Mt2 + t ^ i M " 1 {I, I Mt2 + ti {I, I Mt 2 }
242
.
=
Hence | -M"1^}
I -M"1^} M (7.14)
Hence
aia
1
is
a translation.
Therefore cua * e T for all a s I and
T £ T and so T is a normal subgroup of I.
This
result
isometries.
says
that
we
can
•
almost
commute
translations
and
Since ata ^ £ T where a e I and T E T, we have ata ^ = T'
for some T' E T.
Hence at = T ' a.
That is, if we start with ax we can
move the translation t to the other side of a if we trade x for a different translation T'.
This will be used to simplify some of our expressions.
(T7.15) Theorem:
Let a denote an isometry, let Oi and o 2 denote points
in S and let D = {X
x
,T } denote a basis of T. y' z
Then
where ¡5! and f$2 are the linear components of a with respect to O! and o 2 , respectively.
Proof:
Let { a ^ b ^ C i } denote the vectors in D{oj
in D{o2). column
The first column of M n ,
and {a 2 ,b 2 ,c 2 } those
*(Pi) is [Pi(al')]ri,
U(Oi)
of M n ,
,(P2)
t(Pi(o2)) = o 2 .
Hence
is
[P 2 (a 2 )] n .
g 2 (a 2 )
=
•
By
T7.ll
. and the first oj P2 =
TPJ
xPx(a 2 )
=
TP!(T X (O 2 ))
=
t(P 1 T x )(O 2 )
. t
Since T is a normal subgroup of / there exists a T
IT 1
and t
= P! T x &l^
£
r.
X
such that
= T P X
Hence
5 2 (a 2 )
=
TCT^PJCOJ)
=
T X (I(P 1 (O 2 ))
(R is abelian)
=
T x (°2)
(since T(PI(O2)) = o 2 )
=
P1xxP11(o2)
243
where
Also M ^ i ^ d )
=
MVß/coi)))
=
PI(t
=
Pi(«i)
Since PJT^B!^ c T, there exists p,q,r
M1
and so [ P I ( 3 I ) ] N , . l of M n .
1 PT = 1
.. = [pc/r]^
of
0(0l)(Pl)
Mn,
=M
.(PI)
equal
(since P I fixes Oj)
•
z R such that
, '
x y z
= [P2(a2)]n/-
. ( P I ) equals that of M n ,
columns M
x
(Oi))
i-
Hence the first column
..(P2).
Similarly, the second and third
those
of
Mn,
•
Therefore,
D(0l)(P2)-
Theorem T7.15 tells us a remarkable fact: the component
- (32)
of a is
the
same
regardless
nature
of the choice
of the
of origin.
linear For ex-
ample, if Pj and P 2 denote the linear components of a with respect to Oi and o 2 , respectively, and if f$j is, say, a half-turn about
an
axis
£
through Oi, then p 2 is a half-turn about an axis I' through o 2 where £' parallels I. Besides being important to our derivation of the
crystallographic
space groups, the next several results will enable us to transfer information about a crystal structure that is described in terms of a basis Di(o,) to a new basis and origin D 2 ( o 2 ) . ( T 7 . 1 6 ) Theorem:
Let a denote an isometry, let D = ^ T x ' T y > T z ^ denote
a basis for T and let O] and o 2 denote points in S.
R
o(0l)(a)
=
01
where M is a 3 x 3 matrix and t E R3,
1 t}
'
then
R D ( O j ) ( c 0 = {M | (M - I,)p + t} where p = Proof:
Then if
,
[o2]D(oi).
Let Pi and P 2 denote the linear components of a with respect to
0[ and o 2 .
Since M = M n .
. ( P I ) , T7.15 implies that M = M n , ,(P2). OjJ o2j 244
Let Tj and t 2 be the translational components of a with respect to Oj and o 2 , respectively.
Then
t2 =
x *(o 2 ) =
x iT *
where
Rp
Bi(o2).
translational vector for t 2 with translation such that t p C ° i )
T
Since
-1 t
Pi(o 2 ),
(oj) =
{M | [ t 2 ( o 2 ) ] > D
(a) =
We
respect
= o2.
to
shall
next
Oj
Let
Then
}
.
By
T7.ll,
determine T P
the
denote
the
-1
=
Tit
=
1,1
=
dlTp
-1
- 1
T T P P )(T
Tp)
(T is abelian)
^ ) represents
[ 5 x (o2 ) ]
the translational
to o,. The translational vector of T p 1 , P with respect F i respect to Oj, is represented by —[o 2 ] Since t represents
vector of I with
the translational vector of T j,
12(0!)
= = =
M
t°^D(0l)
l 3 [ 0 2 ]
-
(M- l3)[o2]0(oi)
+ t
D(0l)
+t
t
,
+ t is the translational vector of t 2 with respect to
CM - l3)[o 2 ] ri . D{Oi).
+
[ M ° 2 ) ] D ( 0 i ) - [°*]D(0l)
But the translational vector of t 2 with respect to D{o2) + t by (7.7).
also (M - I 3 ) [ o 2 ] n
R
where p = [o2^
D(o2)(o°
=
{M
1 (M
"
l3)P
( T 7 . 1 7 ) Theorem:
using the R
+
t}
'
D (oj' Let D j and D2 denote bases for T, o denote the origin,
T denote the change of basis matrix from D1 11
is then
Consequently,
to D2
and let r e S.
Then,
representation of r, we have
[r]
Dx (o)
D 2 CO)
{T | [OOO]1"}
The proof of T7.17 is straightforward and is left to the reader. 245
(T7.18)
Theorem:
points in S .
Let D denote a basis for T and let O; and o 2 denote
Let p =
[r]
Then if r t S,
[r]
0(o2) = (la
0(Ol)
I "P>
Again, the proof of this theorem is left to the reader. (P7.14) Problem:
Show that if we move the origin from o x to o 2 and if
we then change the basis from Di to D2,
[r]
D2
we have
[r]
( O J )
Dx (0l)
= {T | -Tp}
where T is the change of basis matrix from D j to D2, r
E
p = [o2]n,
. and
S.
(P7.15) Problem:
A structural analysis of coesite by Zoltai and Buerger
(1959) shows it to be monoclinic with space group symmetry B2/b.
The
coordinates of the atoms determined in the analysis (Table 7.1) define a framework structure of silicate tetrahedra with double-crankshaft chains like those in sanidine, KAlSi 3 O e , a monoclinic feldspar with space group symmetry C2/m.
The structures differ in that the chains in sanidine are
related by a mirror plane whereas those in coesite are related by a glide plane.
Figure 7.4 displays the sanidine structure between 0 and i.
The
origin Oj and basis vectors D j = { a ^ b ^ C j } define the setting of
the
coesite unit cell and 0 2 and D2 sanidine
cell.
= {a 2 ,b 2 ,C 2 ) define the setting of the
The connection between these cells was established by
Megaw (1970) who wrote a matrix for transforming the coesite coordinates to match those of sanidine.
Following a comparison of the resulting co-
ordinates with those of sanidine, she concluded that the coesite structure is impossible for KAlSi 3 0, because there are no enough to accommodate K.
cavities
in
it
large
She also concluded that the feldspar structure
is impossible for coesite because it would require a bridging SiOSi angle of 114°, which theoretical evidence indicates is too narrow for stability (Gibbs, 1982). 246
F i g u r e 7.4: of
the
A drawing of the tetrahedral
double —crankshaft
chains
spanning the structure along
in
[100].
nodes
sanidine
The origin
O x and the D x - b a s i s vectors (Cj is perpendicular to the plane forming a right-handed system) define the setting defined by Zoltai and
Buerger
(1959) for the coesite unit cell, and o a and the D2-basis
vectors
(b2
is
perpendicular
to the
plane forming a right-handed system) define the setting for the sanidine unit cell. d is the change of origin vector.
The vector This drawing
is modified after Megaw (1970).
T a b l e 7.1:
Zoltai
C o m p a r i s o n of the atomic c o o r d i n a t e s of coesite and s a n i d i n e .
&
Buerger
Atom
Sanidine
Megaw
(1959)
(1970)
yi
Ii
Atom
X
I
y
Si,
.1403
.0735
. 1084 -.3597
. 1084
.3168
T,
.7089
.1178
.3444
Si,
.5063
.5388
.1576
.1576
.2175
T,
.0097
.1850
.2233
. 3653
0
. 28S8
0
.1472
0
.1793
.1269
.4025
.1722
.1469
.2244
.0341
.3100
.2574
.0063
0,
0
0
0
0
1/4
0,
1/2
3/4
.1166
0
.1166
0
0,
.7306
.5595
.1256
.2306
.1256
.4211
0,
.3080
.3293
. 1030 - . 1 9 2 0
.1030
.2287
0,
.4877
.5274
.2878 - . 0 1 2 3
.2878
.2103
-1/2
247
°A(2)
"
°A(D °D °B °C
"
(1)
Examine the drawing of the double-crankshaft chains in Figure 7.4 and show that a 2 = aj + fc>! b2 = ca c 2 = -fc>! and [o 2 ] D i = [p] D i = [4i3/4,0] .
(2)
Formulate the 4 x 4 transformation matrix 1 0 {T | -Tp} =
(3)
0 -i
0
0
1
-1
0
i
0
0
0
1
1 0
Use the matrix {T | -Tp} to transform the atomic
coordinates
of coesite (Zoltai and Buerger, 1959) to match those in sanidine and compare your results with those obtained by Megaw
(Table
7.1, Column 3). Let D j and D2
(T7.19) Theorem:
denote bases of T, let Oj and o 2 denote
points in S and let a denote an isometry.
R
02(o2)(a)
=
{
™T~1
1 T[(M
"
Then
l 3 ) P + t]>
*
where R n . . (a) = {M | t}, T is the change of basis matrix from D x to Is 1 vO 1 ) D2 and p = [ ° 2 ] D i ( 0 i ) . Proof:
Consider the following circuit diagram where r e S:
[r] Di(oi)
{T | -Tp}
o2) 1
1 {M | t}
[«Cr)] Di(o,)
[r]
D.(o,)(B) {T | -Tp}
248
t«(r)]D ( O ) 2 2
It follows from the circuit diagram that Rn
. .(a) = {T | -Tp}{M | t}{T | -Tp}" 1
(7.
= {T | -Tp}{M | tHT" 1 | p} = {TMT"1 | -Tp + T[t + Mp]} = {TMT"1 | T[(M - I 3 )P + t]}
.
•
Note that (7.15) expresses the fact that R n . (a) and R n , . (a) U2KO2) i-'lKOl) are similar matrices in the realm of all 4 x 4 real matrices (see Appendix 7). CRYSTALLOGRAPHIC SPACE G R O U P S Not all groups of isometries are suitable for describing the symmetry of crystals.
In Chapter 4, for example, we found the crystallographic
restrictions that must be imposed on point isometries.
In this section
we study the restrictions that must be imposed on groups of isometries that leave the structure of some crystal invariant. a crystal implies that there structure.
is three-dimensional
The very nature of periodicity
in
the
This periodicity is described in terms of a crystallographic
translation group. (D7.20) Definition:
A translation group T
Let o denote a point in S.
is said to be a crystallographic
translation
group
if and only if orb^-(o)
is a three-dimensional lattice whose vectors emanate from o. Note that, by (7.6), if T
is a crystallographic translation group
and if {a,b,c} is a basis for the lattice orbT-(o), then D = { T ,T ,T } T ' x y z is a generating set for T where
T
= a
> T y(°)
v(°)
=
b
T
z (°)
= c
-
That
is, if orby-(o) = {ua + vb + wc | u ,v ,w e Z} then
orb-,- (o) = { T U T V ' T V V ' ( O )
T
and so
(D7.21) Definition:
'
x y z
t U V W , / = {r t t t x y z A
set
of
I u ,v ,w e Z)
,
,
u,y,weZ} ' ' translations D = (T 1 ,T 2 ,ti)
249
of
a
translation group T
crystallographic
T
is said to b e a generating set of
if and only if D is a basis for T and -r '
Let D = { X 1 , T 2 , T 3 }
=
,
U
( T I T
denote
V W 2
I J
a
. I
U,V,W
t
generating
translation group T and let o s S.
,,
Z}
set
.
for
the
crystallographic
T h e n D ( o ) is a basis for the lattice
orby-(o) as shown in the following problem.
(P7.16)
Problem:
Let T denote a crystallographic translation group and
let D = { T 1 j I 2 , T ) } be a generating orb-y-(o) w h e r e o e
set for T.
Show that Lp^^
S.
We shall now turn our attention to groups of
(P7.17)
Problem:
Show that if G
isometries.
denotes a group of isometries, then the
set T of all of the translational isometries in C
is a subgroup of C .
The subgroup T in P7.17 is called the translation (D7.22)
space
Definition:
group
is the
group
A group of isometries C is called a
if the translation group of C
of
C.
crystallographic
is a crystallographic
trans-
lation group.
(T7.23)
Theorem:
Let C
the translation group of C
(P7.18)
Problem:
denote a crystallographic
space group.
Then
is a normal subgroup of C .
Prove T7.23.
(Hint:
See the proof of T7.14 where
C
will play the role of / and the translation group of C will play the role of T.)
Let C
denote a crystallographic
translation group. as shown in P7.16,
space group and
If D =
a
i-s t h 6
the 3 x 3 to D.
n
'- S
let T set
f°
lattice equal to orb^-(o).
then, by T7.15, the matrix representation respect to D{o)
8
enerat:
for the
250
| a E C}
,
then,
with
Let M ^ ( a ) denote
m a t r i x representation of the linear component of a
M 0 ( C ) = {MD(a)
T,
its
If a s C ,
linear component
is the same for all choices of origin O.
Also, let M ^ ( C ) denote the set
denote r
w i t h respect
where C
(P7.19)
is any groups of
isometries.
Let
Problem:
C
denote
{ t , t , t } denote a basis bas for T. x' y' z See (7.12) and (7.13)).
a
group
of
isometries
Prove that M ^ ( C )
and
let D =
is a group.
(Hint:
H e n c e a s s o c i a t e d w i t h each c r y s t a l l o g r a p h i c space group C there is a group of 3 x 3 m a t r i c e s all possible
crystallographic
ciated group of
and a lattice L-,. .. U{ O)
U{u)
space groups
3 x 3 matrices
C
and lattice
that
these linear components (D7.24) origin.
of the
the same asso-
and
Before
Since
isometries
how
in C ,
M^(C)
we will
study
first.
Let a denote
Definition:
share
see
can be constructed.
w e can do this w e must learn more about M ^ ( C ) represents the linear components
We will
an isometry
let o e S denote the
and
T h e n w e d e n o t e the linear component of a by
AQ(a).
If C
A
and A
is
a
group of isometries, then we define A Q ( G ) to be
A Q ( C ) = {AQ(a)
(P7.20)
Prove that A Q ( C )
Problem:
By T7.15, note that
| a £ C}
.
is a group.
for any points
Oj, o 2 £ S,
o!
(C)
are isomorphic since they are b o t h represented by M ^ ( C ) . w e will discover the relationship b e t w e e n M ^ ( C )
(T7.25)
Theorem:
Let
C
denote
Using
o2
(C)
Ao(C),
and
a crystallographic
space group, D =
a g e n e r a t i n g set for its t r a n s l a t i o n group, and o the origin. Then AQ(C)
leaves
invariant.
crystallographic p o i n t
Proof: V e LQ^
Recall
that
Hence
AQ(C)
one
of
the
32
groups.
V
if
if and only if
is
a
[v]^^
vector E
in
% o )
( e )
=
{ M
D(B)
I
3
0 }
and D ( 0 )
(T)
= (I,
I
251
[V]
emanating
S
L e t
Let T denote the t r a n s l a t i o n s u c h that x ( o ) = V .
R
is
D ( 0 )
>
E
AQ(G) Then
from O,
and V £ L
then
Hence R
Since the
D(o)(ikfrl)
translation group
v
Hence [P( )]£)(0) of L p ^ y
z
an
« C or t E Z 3 + [i,i,0] t .
if and only if t2 = tx + t where t E V [-2.5,1.5,-S]1 = {MD([010]2
[-3,l,-3]t + [i,i,0]^ E
| [000]*} E
R
DD (( oO ))
Since
Z 3 + [i,i,0]t,
(C)
The next theorem yields more information on what types of elements t of R 3 can occur in matrices {M | t } in ( T 7 . 2 9 ) Theorem: HII.-jjh
Let C denote a crystallographic space group, let h 1 }
E A (C) be such that h 1 h 1 . . . h A f = h fc
Let D
denote
a basis
for
1hfc +
+
T and
{Mj | t j} , . . . > (M ^ | t ^ } E
R
...hn
2
.
(7.16)
let O E S. C
0(0)( )'
Let M. = M,-,(h.).
i
then
there
D r
If
{I3 | s} E
exists
such that
(MI
I TXHM,
{13
| T,}...^
I -HM
( P 7 . 2 1 ) Problem: (D7.30)
Definition:
f c + 1
| TK}
I tfc
+
= 1 HM f c +
2
I tfc
+
2
)...{Mn
| y
.
(7.17)
Use T7.26 to prove T7.29. Let H denote a point group, let T denote a trans-
lation group and let D denote a basis for T.
If H!,...,H
E H are such
that the relation
h l h I . . . h f c = hfc
+
1hfc +
254
2
...hn
(7.18)
z R3
holds and if M. = M,-.(h.)> then we say 1 that t, 1 , . . . ,t i D r ' ' ' n with
the
relation
{Mj | ^>,...,01 R^(7"). we
say
(7.18)
with
| t } satisfy
respect
condition
T
to
(7.17)
for
consistent
are D
and some
if
{I3 | s} E
In the case where the relation is in the form h 1 h 2 ---h^. = 1, that
t 1( t 2 ,...,t^
tj ,t2 , . . .
is
is consistent.
consistent
with
the
relation
if
That is, if
{Mi I t J t M j | t2)...{Mfc | t k ) = {I, | s}{I3
| 0} = {I, | s}
e
R
0
(D
.
In the terminology of D7.30, T7.29 says that if the relation (7.18) occurs
where
hi,..., h
E
A (C)
and
if
tu-.-.t
E
ft3
such
that
{M. 1I t.} E R „ . .(C) must be consistent J where M. = M~(h.), then t,,...,t 1 / r D(o) i D r ' ' n with the relation (7.18) with respect to T(C)
and D.
This result will
enable us to transfer relations from a point group to its corresponding space groups.
See Grossman and Magnus (1964) for a discussion of
the
generators and relations approach to group theory. By
T7.26,
we
see
that
each
matrix
M
such
that
{M |
TJ.} E
where C is a crystallographic space group, is associated with a collection of elements of C characterized by |{M I t 2 }
{I, | t 2 - tx>
{M I t 2 }
{I3
E
7(C)J =
| t}{M | t x } = {M | t 2 } where {I, | t> e T ( C ) |
= RD(T(C)){H
| t,}
,
the right coset of Rp(7~(C)) with respect to {M | t!). of A Q ( C ) corresponds to a right coset of
T(C).
Hence each element
This
correspondence
yields an isomorphism from A Q ( C ) to
G/T(C).
(P7.22) Problem:
to R D ( o ) (C)/R D (T (C)) defined by
Prove that e : A Q ( C )
6(&) = R 0 (7~(C)){M | t} where M = M ^ B ) and {M | t} z isomorphism
(you may
choose
to
skip
R0(o)(C)
is
an
this problem on first reading).
Conclude that A Q ( C ) is isomorphic to C/7"(C). We are now ready to give a clear statement of how we will construct all of the crystallographic space groups C.
Let H denote an oriented
point group and let L denote a lattice left invariant by H.
Let P denote
that basis for the primitive sublattice of L associated with H and let O denote the origin. sponds to L by
.
Then we denote the translation group that correThat is
255
TL
= {T E r | X(o) £ L}
Let M p ( H ) = {M,,Mj,...,M }. R
3
.
(7.20)
Then we seek all possible
T L ^ , . . . , !
E
such that
Rp(C) = RpC7'z_)[{M1 | t1},{M2 | t 1 },...,{M n | t n >]
(7.21)
for some crystallographic space group C such that Rp(7~(C)) = R p (7" L ) and
(7.22) Mp(C) = MPCH) By
finding all such sets
crystallographic
space groups
.
{^,...,1 } we will
find
all
of
the
(through their matrix representations).
The strategy that we will use to obtain these sets is to determine
a
sufficient number of relations on H so that a set {tj ,t2, . . . ,t } yields an Rp^ o ^(G) if and only if the set is consistent with all of these relations . Once all of the crystallographic space groups satisfying (7.22) for some choice of H and L are found, we will need to classify them into space group types. employed.
To do this, many different equivalence relations have been
Some of these are discussed by Hans Wondratschek in Chapter 8
of ITFC (Hahn, 1983).
We shall use an equivalence relation that gives
rise to the traditional 230 crystallographic space group types. idea behind this relation is relatively simple.
The basic
Suppose C j and C 2 are
two crystallographic space groups. If there exist points Oj and o 2 and generating sets D^ and D2
of T(GI)
and 7~(C2) such that Di(oJ
D 2 ( o 2 ) are both right handed and R n , , (C x ) and R n •JI(OI) same set of matrices, then C1
and C 2 are equivalent.
,
and
,(C 2 ) are the
Hence to show that
C j is equivalent to C 2 we show that, by a change of origin and generating sets, the matrix representation of one can be converted into that of the other. In view of T7.16 we have the following definition. (D7.31) Definition:
Let C j and C 2 denote crystallographic space groups.
Then Cj is equivalent to C 2 if and only if there exists a vector R
3
r E
and an integral matrix T with det(T) = 1 such that the matrix rep-
resentations {M | t} of the elements of Cx with respect to D, a generating set for 7"(C), become those of C 2 by the transformation 256
{TMT-1
01 I t}
I T[(M - I,)p + t]}
When discussing a space group C where orb-y-^^(o) is
a
centered-
lattice, we will usually write the matrices representing A ^ C C ) with respect to the basis P of the primitive lattice.
However, in order to test
for equivalence, D7.31 requires that {M | t} be written with respect to a basis D that generates T(C).
While this is a serious problem relative
to the change of basis matrix T, we need not change to the basis D in order to detect equivalence that occurs because of a change of origin as the following theorem shows.
Let a and (5 denote isometries, let D
(T7.32) T h e o r e m :
and P
denote
bases of T, 0[, o 2 t S and T be the change of basis matrix from D to
P.
Then R
D(oi)(a)=R0(o2)(fJ)
R
P(°i)(a)
if and only if
Proof:
R
P(O2)(P)
Suppose R D ( 0 i ) ( a ) = R D ( 0 2 ) ( P ) .
where V £ S,
R
=
D(o2)(^
If
R
D(o1))(a) =
{M
I
[v]
DC0l)}
then R n . (3) = {M | [ w ] n , . } where W is such that U(o1) L>{ o i j
=
{M
I
(M
- ^ ^ ^ ( o j
+
^ ( o ^
=
{M
I
[V]
D(0l)}
•
Hence R p ( o i ) ( a ) = {TMT" 1
| T[v]D(oi)>
and
R p ( 0 i ) ( P ) = iTMl" 1
| T[w]D(oi)>
Then R
P(o2)(e) = i ™ 1 " 1
I
(
™ T " 1 " l3)[o2]p(oi) + T[W]0(Oi)>
= {TMT" 1
| T(M - I 3 ) T " 1 [ o 2 ] p ( o i ) + T [ w ] D ( 0 i ) }
= {TMT" 1
| T[(M - l 3 ) [ o 2 ] 0 ( O i ) +
(Since T _ 1 [ o 2 ] D ( o i ) = = {TMT" 1 =
R
P(
0 l
[W]D(0i)]}
[o2]D(0i))
| T[V]D(oi)} )^
•
The converse is proved in a completely similar fashion.
257
By T7.32, we may use the basis P of the primitive lattice to detect equivalence due to change of origin.
However, one must change to the
basis of the lattice under consideration to detect equivalence due to a change of basis. C R Y S T A L L O G R A P H I C SPACE GROUP OPERATIONS When an oriented point group H and a lattice L are given, to find the space groups satisfying (7.22) we must search for sets of elements in R3 that are consistent with the relations in H. = 1 is one relation that is always present.
Let h E H.
Then
The next theorem gives
the constraint that is imposed by this relation. (T7.33) Theorem:
Let h be a point isometry, let T denote a translation
group and D be a basis for T.
Then t is consistent with the relation
ho(h)= 1 W i t h respect to T and D if and only if {I 3 | Nt} t RQ(.T)
where
N = M + M 2 +...+ M0(-h:) and M = M^Ch). Proof: to T.
Suppose t is consistent with the relation h 0 ^ ' ' = 1 with respect Then {M | t}°(h:) = {I3 | s} E Rp(7).
But note that
(M | t } 2
=
{ M 2 | Mt + t}
{M | t} 3
=
{ M 3 | M 2 t + Mt + t}
{M | t } ° ( h )
=
{M°(h)
| M ( ° ( h ) _ 1 ) t +...+ Mt + t} .
But {M | t } ° ( h ) = {I, | s}. Since M ° ( h ) = I 3 , t = M ° ( h ) t and so, by rearranging terms, we have S = (M + M 2 + ... + M ° ( h ) ) t = Nt . By reversing this argument the converse is also proved. The constraint described by T7.33 gives rise to two new types of isometries.
The screw and glide operations. 258
•
( E 7 . 3 4 )
Consider a space group
E x a m p l e :
R p ( T ( C ) )
=
Let P
R p C T p ) .
=
denote the basis chosen in Chapter
{ a , b , c }
6 with C along the axis of 4 ,
a and b perpendicular to C with Y = 90°
such that D is a right-handed system.
M =
Furthermore,
since
the
o r b - j - ^ (O)} is Z . V
where N = M + M
p
( 4 )
=
lattice
Then
0
- 1
0
1
0
0
0
0
1
type
is
{[v]^
primitive,
| V c
Then by T7.29 and T7.33, if {M | t} E C, then Nt £
3
2
M
such that M p ( G ) = M p { t ) and
C
+ M 3 + M*.
Calculating N we obtain
N =
0
0
0
0
0
0
0
0
4
Hence Nt E Z 3 implies that 41 3 E Z. Hence to be consistent with 4 " = 1 ,
t
must be chosen such that t3 = 0, i, | or 3/4.
•
The
operations
found
in E7.34 are {M | [000]*}, {M | [0,0,i]t},
{M | [O.O,!]1^} and {M | [0,0,3/4]*} where M = quarter-turn
represent
screw
operations.
Mp(4) .
These
matrices
The translational component
of each of these is directed along the axis of the rotation which in this case is along C.
Hence, under {M | [0,0,i]*} a point [xyz]t is rotated
a quarter turn about C and then displaced a distance of C/4 to the point [-y,x,i
+
2 ]
t
.
Consequently, this operation is called a quarter-turn of c/4 and will be denoted 4j.
screw with a screw translation
Since the
screw translation of {M | [000]*"} is 0, it is merely a quarter-turn and will be denoted by the usual symbol 4 . [xyz] t
to
[~y,x,i
+ z] 1 ".
The operation {M I [00*]L} maps
Since the screw translation
quarter-turn screw will be denoted 4j.
presents a quarter-turn screw denoted 4^. tional convention that
Tuvwl
n
m
is C/2, this
Similarly, {M | [0,0,3/4]t) reIn general, we make the nota-
represents an n
th
-turn screw about the
vector ua + v b + wc with a screw translation of mr/n
where
shortest (nonzero) vector in the lattice in the
direction.
symmetry
element of a screw
associated rotation.
operation
[t/vw]
r
is the The
will be taken to be that of its
Hence in the case of a primitive cubic lattice,
259
^ ^^
denotes a third-turn screw about [111] with a screw translation
of 2/3(a + b + c) since a + b + C is the shortest nonzero vector in the [111] direction.
However, in the body-centered cubic
represents a third-turn screw about
lattice,
[111] with a screw
translation
of
(2/3) (|a + 4-b + i c ) = (l/3)a + (l/3)b + (l/3)c since |a + +b + ic is the shortest nonzero lattice vector in the direction [111]. (P7.23)
Problem:
Show that with respect to the primitive cubic lattice
P, the Seitz notation for
is
{M | [2/3,2/3,2/3]^}
where M =
,
and P is the basis for the primitive lattice given
in Table 6.3.
(P7.24) Problem:
Find the Seitz notation for
with respect
to
the body-centered cubic lattice / described in Table 6.3.
(P7.25) Problem:
Write the full 4 x 4
matrix for the screw
operations
discussed in P7.23 and P7.24.
(P7.26)
Problem:
Find the Seitz notation for
with respect to a
primitive cubic lattice P .
(P7.27) Problem:
Find the Seitz notation for
body-centered cubic lattice /.
with respect to a
Note that your answer here should be the
same as in P7.26.
(P7.28) Problem:
Find the Seitz notation for
with respect to a
primitive hexagonal lattice.
(E7.35) Example:
Consider the space group C of E7.34 based on 4
but
with a body-centered lattice type I.
The basis D
in E7.34 and so M and N are the same.
However { [ V ] ^ | V E orb^-^^(o)}
is now Z 3 + Zfi.i.i] 1 .
Since Nt =
[0,0,4t 3
there must exist a
[ v'iv 2 v 3 ] T E Z 3 and an n z Z such that [0,0,4t 3 ] t = [ v 1 v 2 v 3 ] t +
260
is the same here as
i
nt
V =
Since V i + ni
= 0 and v
n e Z,
l t
n = 0.
Hence 4t 3 e Z.
as in E7.34, we obtain only the operation 4 ,
4t,
42
Consequently,
and 4 3
for a body-
centered lattice left invariant under 4.
(E7.36)
Example:
•
Consider the space group C based on the point group
m with lattice type P (in the second setting with Y as the unique axis). Then 1 M = Mp(
[010]
0
o"
0 - 1 0 .
m) =
0
0
1
Nt = [2t J, 0, 2t j ] E Z 3
and so t1
If we take ti = i and t3
= 0 or \ and t3 = 0 or
a point [x,y,z]^"
is reflected across the plane (010) and then translated
parallel to it a distance of a/2 along [100]. a glide glide
operation,
(010) is called the glide
translation.
Such an operation is called plane
and a/2 is called the
The reflection plane of the mirror part of the glide
operation will be taken to be its symmetry element. translation 1
t° °]a.
is
a
along
this
glide
is
called
an
Because the glide a-glide
denoted
by
In the case where fj = t3 = -J, the glide translation is |a + |c
which again parallels the (010) plane. glide
= 0, then
translation
called an n-glide.
is not
This type of glide (where
the
in the direction of a basis vector) will be
The glide planes that arise in our example are listed
below (note that a mirror operation is a glide with a 0 glide translation modulo the translation group).
Symbol t j 0 1 2 0 1 2 (P7.29) the
Problem:
lattice
axis).
t3 0 0 2
A.
i
I
Glide
of
Operation [010] m [010] a [010] c [010] n
I
Type
reflection a-glide c-glide n-glide
Consider the space group C described in E7.36 where
type P is taken to be in the first setting (Z the unique
In this case the mirror plane is perpendicular to c .
261
Show that
m, a , b and n (recall that
the following glide operations are possible:
when no orientation symbol is given, [001] is assumed) where the glide translation of the n-glide is ia + -Jb.
(P7.30)
Problem:
Show that the glide translations of the glide
oper-
ations in P7.29 are unchanged if an /4-centered or a S-centered lattice is used instead of a primitive lattice.
Show that, in E7.36, the result
is unchanged when P is replaced by an /4-centered or C-centered lattice.
For a beautifully illustrated discussion of space group operations, see Bloss (1971) Chapter 7.
THE CRYSTALLOGRAPHIC
SPACE GROUP T Y P E S D E R I V E D FROM T H E
ONE-GENERATOR
P O I N T GROUPS
Given an oriented point group H,
a lattice L left invariant under
H and the basis P for the primitive lattice, the results stated thus far give us conditions that must hold for an {M | t} to be in Rp^^iG), G
is a space group satisfying (7.22).
essary
and
Rp(T^)
sufficient
conditions
Theorem T7.37 below states nec-
for
generate Rp(C) for some C
generator point group.
where
a t
to be such that {M | t} and
satisfying (7.22) when H
is a one-
By a one-generator group we mean a cyclic group.
Such a group H has an element a such that H = { a , a
2
,...}.
These
groups are 1, 2, 3, 4 , 6, 7, m, 3, 4 and 6.
(T7.37)
Theorem:
Let L denote a lattice left invariant by
generator point group H
the
one-
generated by a and let P denote the basis for
the primitive sublattice of L that is associated with H.
Let M =Mp(a).
There exists a crystallographic space group C satisfying (7.22) such that each element of Rp^ o ^(G) can be written in the form
{I3 where { I 3
| v}
| r}'
,
E R p ( 7 " ^ ) and 1 < /' S 0(a) if and only if r
with the relation
Proof:
I vHM
= 1 with respect to T^
is consistent
and P.
If there is such a crystallographic space group C , then, since
262
{M | r> £ a°(
a
Rp^CG),
) _ i
reSpect
by
T7.29, r must be consistent with the relation
to T ^ and P.
Now suppose that r is consistent
with a0(-a^ = 1 with respect to T ^ and P.
By (D7.30),
{M | r} o ( c ° = {I, | s}
where {I3
| s} E Rp(7~^).
,
(7.23)
We will use (7.23) to show that the set
K = R p (7" L ){{M | r}' | / = 1, . . • ,o(a)} is closed.
Let A = {I3
| s^iM
| r}' and B = {I3
| S 2 }{M | r}' be ele-
ments of K where Sj and s 2 are triples representing lattice vectors with respect to P
and where 1 < /',/' < o(ot).
Then {M | r}' = {m' | p} for some
p E R 2 and so
{M | r}'{I3 | s 2 } = {f/ I p}{I 3
| sj}
= {M' I p + M'S2} = {I, | M'S2}{M' I p} = {I, I M'S 2 HM Since L
is invariant under H,
I r}'
.
(7.24)
M'S2 is a triple representing a
vector in L with respect to P.
lattice
Hence
AB = {I, | s j ) {M | r>'{ 1 3 | S 2 H N
= {I, | S L }{I 3
I M'S2HM
I r}'
I r)'{M | r}' =
= {I, | S L + H'S2){M I r}' + ' .
where
{I3
| SI + M'S2} E Rp(T^).
If /' + /'< o(a) , then {M | r}'
in {{M | r}' | /' = 1, . . . ,o(a)} and so then AB is in K. then setting k = i + j - o(a) {M | t}' + ' = {M | t}° ( a ) {M
By (7.23) , we have, 263
| t)k
.
+
1
is
If o(a) < / + /',
I s}{M I r )
AB = {I, I S l + M ^ H I ,
= {I,
where {I3 | S 3 } E R ( s i n c e
k
I r}
I S,}{M
k
,
R p ( T i s
closed)
1 < k < o(a).
and
Hence AB E K.
(P7.31)
Problem:
Rp(T.
Suppose that A = { I 3
| SjMM | r } '
where
{I3
A" 1 = {I3 1
by confirming that AA
| - M o ( a ) - '"(s + si)}{M | r > o ( a ) " ' | 0}.
= {I3
(Hint:
use (7.23) to help with the
Now show that A ^ is in K.
simplification).
Using P7.31, we have completed the proof that K is a group. K = Rp(C)
for some space group C .
satisfied.
By the way K was constructed, Mp(G) = Mp(AQ.
Rp(T(C)) = Rp(F^) {I3 | t } (P7.32)
| Sj} e
Show that
we
show
To show that
that the only elements of the form
are those where t represents a lattice vector in L.
in Rp(G) Problem:
1 < /' < o(a).
shall
Hence
Now we need to show that (7.22) is
Suppose
Show
that
m' =
| t} =
{I3 I3
and
| s^íM
{I3
so /' =
o(a).
| r}' Then
where show
that
{I3 | t> e Rp(7" L ) and that R p ( r ( C ) ) = R p ( T ¿ ) . Since we now have T(C)
isomorphic to L,
we have also shown that
C
is a crystallographic space group. (E7.38)
Example:
•
Find all of the crystallographic space group types C
such that Mp(C) = M p (6). Solution:
From Table 6.3, the only lattice type left invariant under 6
is the primitive lattice P with basis P such that
1 - 1 0 M = Mp(6) =
1 0 0
264
0 0
1
Consider {M | r}.
By T7.33, we need to find all vectors r such that Nr
represents a lattice vector.
Then by T7.37 we will have found all of the
crystallographic space groups C that satisfy (7.22) with H = 6 and L = P.
Since the lattice is primitive
R p i T p ) = ({la
I s} I s
Z3}.
E
Since N = M + M 2 + M 3 + M* + M 5 + M e , we have
0 N =
0
0
0
0
0
0
0
6
and so Nr = [0 0 6r 3 ] , which implies that 6r 3 must be an integer.
Hence,
we have the generators
{M | [ f , / , ^ ] 4 } . {M | [r 1 ,r2 , (1/6) ] t }
, {M | [ri
{M | [ r . / i J ] ' ) , {M | {r l ,r 2 ,(2/3)] t >, {M | [rltr2,
Since
and r2
are equivalent under D7.31. position to some vector p ,
If the origin is shifted from its current
then
becomes {M|
(M - I 3 ) P + r)
.
But "0 -1 (M - I,)p + r =
1 -1
0
P2
0
0
P3.
0
Pi - P2
i
a
nd Px = rt
+
- r 2 , then
265
r2 r
r i +
r2 r
0
r
'ri
0' Pi
-P2 =
of
However many of these
{M | r)
=
(5/6) ] t } .
can take on any values, we have an infinite number
crystallographic space groups associated with 6.
If we set p2
,r2 , (1/3) ]*} ,
3.
3.
0 (M - I 3 )p + r =
0 r3.
Hence by an appropriate choice of origin, each of the generators we have found
can
be
written
in
the
form
{M | [0,0,Tj]1"}.
For
example
{M | [ 0 , 0 , 1 / 6 ] i s the representative of the infinite number of space groups generated by the elements of the form {M | [Tj ,r2,1/6]*"}.
Hence
every space group C with Mp(C) = Mp(6) is equivalent to one generated by one of
{M | [0,0,0^}, {M | [0,0,1/6]*}, {M | [0,0,1/3]*}, {M I [0,0,i)]1}, {M | [0,0,2/3]*}, {M | [0,0,5/6]1} Since
.
(M - I 3 )p has a zero in the third component, a change of origin
does not affect the third component of r.
Hence the only way two of these
generators, say {M | [0,0,1/6]*}
and {M | [0,0,l/3]t>
can lead to equivalent space groups is if there exists a proper unimodular matrix T such that {TMT"1 | T[0,0,l/6]t} = {M | [0,0,l/3]t} . It can be shown that no such matrix T exists.
In fact all six of the
generators lead to nonequivalent space group types.
Hence we have found
six nonequivalent space groups generated by G, Gj, 6 2 , 6 3 , G s and respectively.
denoted P6,
P6lt
G5,
Since these all have the primitive lattice P, they are
P62,
P63,
P6,, and P6S.
•
A brute force technique for showing that the six generators found in (E7.38) are nonequivalent can be developed along the lines of the argument used at the end of Chapter b.
More elegant approaches require the
development of further algebraic tools. book to develop those tools.
We do not have the space in this
Hence we will leave this detail unexplored.
266
(E7.39) E x a m p l e :
Consider the space group P A c c o r d i n g
to E7.38
and
T7.37,
6 RpCfii)
=
U Rp(7 /'= 1
){M
=
Rp(7~p){M
I r}
U
where falls
M = Mp(6)
RpCTp){M
and
| r}'
| r}"
R
U
I [0,0,1/6]1}, R p ( r p ) { M 2
Rp(7"p){M"
|
[0,0,2/3]*},
R
p
(r
p
(r
p
| r}5
){M
5
r}3
|
Rp(7"p){M
U
each
element
| r}6
of
,
P6!
cosets:
| [0,0,1/3]1},
){M
Rp(7"p){M
U
Consequently
in e x a c t l y o n e o f t h e s i x r i g h t
Rp(7>){M
p
[0,0,l/6]t.
r =
I r}1
Rp(7"p){M
U
|
[0,0,5/6]1},
Rp(rp){M3
R
p
(r
p
){I
[0,0,i]t>,
|
I
3
[OOO]1},
where 1 - 1 0 M
1
=
0
0
W e shall now describe the elements in R p ( T p ) { M 2
an element
1
0
0
1
0
0
0
1
0
0
0
1
where u , v , w for
u
0
analyzing
-1
0
0 "
V
1
-1
0
0
w
0
0
1
0
0
0
since
the
we
find that
the
the
matrix
cussed by Wondratschek
The
points
of
"o
-1
0
1
-1
0
1/3
0
0
1
1
0
0
0
=
lattice
in
(7.25)
and
defines
v)a +
this
that appear
form
V 1/3 + W 1
Boisen
267
the
and
a third-turn
techniques
Gibbs
screw
dis-
(1978),
operation in
the
axis
in the u n i t cell are t h o s e
for
point
(1/3) (t/ + v ) b
which
Using
occurring about an
to c p a s s i n g t h r o u g h t h e
(1/3) (2u -
example
of a space group operation
(1967)
((1/3) + w ) c
For
form
u
is p r i m i t i v e .
representation
w i t h a screw t r a n s l a t i o n of direction parallel
in e a c h o f t h e s e c o s e t s .
and Neubuser
matrix
1
| [0 ,0, (1/3) ] t } is of t h e
0
e Z
0 0
.
0 < (1/3)(2u - v) < 1
and
0 < (1/3)(u + v) < 1
Adding the corresponding terms of these inequalities we have 0 < u < 2 .
Since u is an integer, u can only equal 0 or 1.
When u = 0, the ine-
qualities become 0 < —(1/3)v < 1 and 0 < (1/3)v < 1. that v < 0 and the second that v > 0.
The first implies
Hence, when u = 0, v must equal
0. When u = 1, a similar analysis shows that v can only be 0 or 1. when u = 1, V can equal either 0 or 1. located at the origin,
Thus, besides the
Hence,
operation
there are two others in the unit cell passing
through the points [1/3,2/3,0]^ and [2/3,1/3,0]t, respectively.
An ele-
t
ment in the coset R p C r p ) { M " | [0,0,2/3] > is of the form 1
0
0
u
-1
1
0
0
1
0
0
0
0
0
-1
0
V
-1
0
1
w
0
0
0
1
0
0
1
0
0
0
1
2/3
-1
0
0
0
0
1
0
1
0
0
0
u V 2/3 + W 1
An analysis of this matrix shows that it defines a negative third-turn screw operation (3
occurring about an axis passing through the point (1/3)(u + V)a + (1/3)(2v - u)b .
Consequently, besides the (3 others in the unit
cell passing
[2/3,1/3,0]^, respectively. (3
operation at the origin, there are two through the points
[1/3,2/3,0]t
and
This is as one would expect, since (3^)^ =
and this composition does not move the axis of the 3^ operation.
(P7.33) Problem:
Analyze the matrices in each of the remaining cosets
of P6i and show that the axes are positioned as shown in Figure 7.5. (P7.34)
Problem:
Let x denote the translational isometry defined by
t(o) = t where t = 2a + 3b + 5c and P = {a,b,c}.
268
Show that
Y
Figure 7.5:
A diagram of a unit cell containing the screw axes of space group P6i each
taking place about rotation axes paralleling c .
The 6;-screw axis is symbolized by a pronged
hexad, the 3!-screw axes by pronged triads and the 2i-screw axes by pronged diad symbols.
Figure 7.6:
A diagram showing the compos ition of the trans 1ational
isometry x where
T (o) = 2a + 3b + 5c = t with the rotational screw operations comprising a 6x-screw axis that parallels c and passes through the origin.
The resulting operations formed by this compo-
sition take place about rotation axes paralleling c and are located on the perpendicular bisector of t at a distance of t/2ctn(p/2) from the line from O to t where p is the turn angle of the rotational component of the screw operation.
269
1 0 RpOO =
Find
0
0
1 0
0
0
0
0
2 3 1 5
0
1
Rp(ta) for each of the six coset representatives a enumerated in
E7.39 (For example, find Rp(ia) where Rp(a) = {M | [0,0,1/6]t}).
Observe
that these axes are located at points along the perpendicular bisector of the line segment £ from O to t as shown in Figure 7.6.
The distance
of the axis of xa from £ is (i/2)ctn(p/2) where p is the turn angle of the linear component of a and t = ||t||.
This formula can be derived by
noting that xa maps the Z axis to the line parallel to the Z axis passing through the point t.
(P7.35) Problem:
Consider the space group P62 •
Then
6
Rp(P62) = U R„(rp){M | r}' /= 1
where M = Mp(6), r = [0,0, l/3]t. P62
Locate all of the axes of elements in
that pass through the unit cell.
in the ITFC (Hahn, 1983, p. 546).
Check your answer with that given
Note that your drawing should not in-
clude those shown in the table for [r 1 ,r 2 ,r 3 ] t where Tj or r 2 are equal to 1. (P7.36) Problem: (D7.40) Definition:
Do P7.35 for P6,.
(In this case r = [O.O.i]^.)
Let C denote a crystallographic space group and let
P denote the basis of the primitive lattice associated with A Q (G).
Then
each right coset of Rp(7~p) in Rp(C) has a representative of the
form
{M | r} where r = [ r 1 , r 2 , r i ] t sentative is called a principal
(P7.37) Problem:
and 0 < r. < 1 for each /. representative
of C with
Such a reprerespect
to
P.
Use (7.24) to prove that Rp(Tp) is a normal subgroup
of Rp(C). (P7.38) Problem:
Show that the principal representative defined in D7.40
exists for each coset of R p ( T p ) in R p ( C ) and that there is only one such
270
representative for each coset.
(P7.39) P6lt
Problem:
Using E7.39, find the principal
with respect to P,
representatives
of
the basis for the primitive lattice associated
with C.
( D 7 . 4 1 ) Definition:
Let C denote a crystallographic space group and let
[xyz]*" denote a point that is moved by each isometry of C .
Then the set
of images of [xyz] t under the principal representatives of C with respect to P is called the general
position
of C
in the set are called the general
(cf. Hahn, 1983).
equivalent
positions
The triples
of C
(Henry and
Lonsdale, 1952).
Suppose that we know the triple that is the image of [X,y,z]*" with respect to a basis P under an isometry a and wish to find the 4 x 4 matrix representation
Rp
of
a
with
t
[fi(.x,y,z),f2(x,y,z),f3(x,y,z)]
respect is
the
to
P.
image.
Suppose
Then /\(x,y,z)
V = is
a
linear polynomial for each 1 £ / £ 3 and
X
^ 11
r
y
r
r
z
—
21
r
1
!1
12
22
r
13
tl
r
23
y
32
f3 I
z
0
0
r
0
1
fi(.x,y,z)
X —
f3(x,y,z)
1
1
Hence we obtain the following set of polynomial identities:
r ii* + r12y
+ rl3z
r 21* + r22y
+ r 2 3 z + t2 =
+ t1 = ^ ( x , y , z )
r 3 1 x + r32y
+ r33z
f2(x,y,z)
+ t3 = f-,{x,y,z)
.
Therefore, r., , r.„, r.„ and t. are the coefficients of f.(x,y,z). ' /1' / 2* / 3 / /
For
example, if the image of [x,y,'Z]^ under a is [(3/4) + z,(l/4) - y,(3/4) - x]fc
,
then r
u
x + r12y
+ r 1 3 z + ti = Ox + Oy + lz + (3/4)
implying that r 1 1 = r 1 2 = 0 , r 1 3 = l and ti=3/4. 271
Continuing this reasoning,
we see that
R
Consequently, the 4 x 4
P(0)(a)
Example:
0
1
3/4
0
-1
0
1/4
-1
0
0
3/4
0
0
0
1
=
representative of a can be found by an inspection [x.yjZ] 1 ".
of the corresponding image of
(E7.42)
0
Find the general equivalent positions of P6
In P7.39, the principal
Solution:
representatives
of P61
with
respect
to P are {M | [ 0 ,0,1/6 ] t } , {M 2
| [0,0,1/3]*}, {M 3
| 0,0,i] 1 },
{M* | [0,0,2/3]*}, {M 5
| [0,0,5/6]1"}, {I 3
| [000] t >,
where "l
M =
The images of [x,y,z]
- 1
1
0
0
0
0"
0 . 1
under these representations are
[x - y , x , (1/6) + z] t ,
- y , (1/3) + z] t , [-x ,-y
[~y,x
[y - x ,-x, (2/3) + z] t , [y,y - x,(5/6) + z f ,
+ z]1,
[x.y.z]1
.
These triples are the general equivalent positions of P61 .
(P7.40) P63.
Problem:
the
general equivalent positions
for P62
and
Verify your answers with the results given in (Hahn, 1983).
(E7.43) C
Find
c
Example:
Find all of the crystallographic space groups
types
such that A (C) is isomorphic to 2.
From Table 6.3, the
Solution: P and C Hence
lattice types left invariant under 2 are
(where we have chosen the setting where Y
we
Mp(^'^2).
seek
crystal lographic
With respect to P,
space
we have
272
groups
C
is the unique such
that
axis).
Mp(G) =
- 1 0 10
M = M p (I° ^2) =
We will find the space groups C
such
0
0
1 0
0
0 - 1
that
Rp(7~(G)) = Rp(7~p)
1 P E Z
'} '
first.
By T7.37, since
V
=
V
{{l3
we seek those elements of r e R3
1 r}
-26)
such that Nr e Z 3 where
0 N = M + M
Hence Nr =
(7
=
[0,2r2,0] must be in Z 3 .
0
0
0
2 0
0
0
0
Therefore, modulo P, we have the
generators {M I [ r ^ O , ^ ] * } where rit
r 3 t R.
and
{M | [ r 1 , i , r 3 ] t >
(7.27)
By T7.37, the generators in (7.27) yield all of the
space groups C that satisfy (7.22) for H = To
,
and L = P.
find a list of the nonequivalent space groups from all of the
space groups based on (7.27), we determine the impact of moving the origin to p .
If this shift is made, {M | t } becomes {M | (M - I 3 )P + r} = {M | [-2p l ,0 ) -2p 3 ] t + r]
.
Choosing p ! and p 2 so that 2pj = Tj and 2p 3 = r2, we see that each of the generators in (7.27) is equivalent to either {M | [000]1"}
It
{M | [0,i,0] t )
or
can be shown that these are nonequivalent.
crystallographic
space
group
types
where
Thus we have found two Mp ( C ) =
M
and
R p ( T ( C ) ) = R p { T p ) . We call the space group generated by {M | [OOO]1"}, P2, and that generated by {M | [0,i,0]t}, (P7.41)
Problem:
Consider the space group P21.
273
Locate all of the sym-
metry axes in this space group that pass through the unit cell, find the principal representatives of P2i with respect to P, and calculate set of general equivalent positions.
its
Compare your results to those in
ITFC (Hahn, 1983).
Continuing with E7.43, we consider the case where the lattice left invariant under 2 is taken to be C .
Even though the basis of this lattice
is D = {-Ja + ^b,b,c), we continue to write all of our matrices in terms of the basis P.
Hence
w j[I3
I s}
=
1
where m E Z 3 and u = 0 or ] j
S = m + uti.i.O] "
Consequently, we seek those elements r =
[r 1 ,r 2 ,r 3 ]^ E R3
the condition that Nr represents a lattice vector.
[O^ri.O] 1 = m + u[i,i, 0]*
where u = 0 or 1.
(7.
that satisfy
That is, such that
,
Then 0 = m^ + ui where m , E Z.
Hence u = 0 and so,
as in the case of P, we have the generators
{M | [/• 1 ,0 J r 3 ] t }
and
{M | [ r ^ ^ r , ] * )
.
As before, these are equivalent to
{M | [000] t }
respectively.
In
and
particular
{N | [O.i.O]*} ,
{M | [0,^,0]*"}
1
is
(M I [i.ijO] "} where we have chosen Tj = -J and r3 = 0. {M I [i.i.O]*} = {I, | [¿,i,0]t}{M
and since {I3
Rp(7" c ){I 3
| [bi.O]1} E
R
P
| [000] t >
,
| [OOO] 1 } =
| [OOO]*) U R p ( 7 c ) { M
| U.i.O]1}
and so {M | [000]t} together with R p ( T q ) generates the same group of
274
to
Note that since
{ T ,
| [000]t} U R p ( f c ) { M Rp(7" c ){I 3
equivalent
matrices as that generated by {M | [i,i,0] } and Hence groups.
equivalent
space
Consequently we obtain only one space group denoted C2.
{M | [000] } and
Hence
there are three distinct
{M | [0,i,0] } generate
crystallographic
monoclinic point group (E7.44) Example:
space groups
based
on the
They are P2, P2j and C2.
•
Find the principal coset representatives of C2 with
respect to the P basis and the set of general equivalent positions
of
C2.
Solution:
By (7.26) and (7.28) we see that R p ( T c ) = Rp(7-p){I, I [000]t} U R p (7~ p ){I 3 I [i.i.O]*} = Kp(.Tp)
U
R p y( . T p ) P P
{I,
I [i.i.O]*)
.
But R p ( C 2 ) = R p ( r c ) { I , | [000]t}U R p ( 7 c ) { M | [OOO]1"} where M =
.
.
Hence | [U,0]t}j{M
R p ( C 2 ) = ^Rp(Tp) U R p C T p ) { I 3
| [000]t}
U [ R p ( r p ) U R p (7~ p ){I 3 | [i,i,0]t}]{I3 | [OOO]1") = R p ( r p ) { M | [OOO]1} U Rp(7"p){M | [i,i,0]t} U Rp(rp){i3 The
principal
coset
I [ooo]*} u R p ( r p ) { i 3
representatives
of
C2
with
| [i.i.on* .
respect
t
{M | [000] > {M | [i.i.O]*}, {I, | [000]*), {Ij | - 1 0
Mi
.
to
P
Since
0
0
1 0
0
0 - 1
the general equivalent positions for C2 are [-x.y.-z] 1 , [i - X,i + y,-z] t ,[x.y,*]* and [1 + x +
275
y.z]*.
are
(P7.42)
Problem:
Show that the set of all crystallographic space group
types C such that A Q ( G ) is isomorphic to 3 consist of P3,
P3 j,
P32
and
R3.
Applying the techniques illustrated in this section one can verify that the one-generator point groups give rise to the following list of 30 crystallographic space groups. 1:
PI P2,P21,C2
2:
3:
P3,P31,P3Z,R3
6:
P6,P61,P62,P63,P6h,P6i
1:
PI
m:
Pm,Pc,
3:
THE
Cm,Cc
P3,R3
4:
P4,14
6:
P6
CRYSTALLOGRAPHIC
S P A C E GROUP T Y P E S
DERIVED
FROM T H E T W O - G E N E R A T O R POINT G R O U P S The two generator point groups H contain two elements a and (5 such that each element of H
is expressed
1 < / < o(a) and 1 < j < o(P).
uniquely
in the
form a'fs' where
In order to do this, the elements a and
fi must be related in a special way.
For each point group, we will choose
a and 3 such that 3 = a ¡5a and such that D
= {1}.
A listing of the two-generator
(7.29 point
groups together with their generators is given in Table 7.2. (P7.43)
Problem:
Show
that the a and g listed for each of the two-
generator point groups satisfies (7.29). (P7.44) Problem:
Show that
n = {1} for each a and fS pair given in Table 7.2 where denotes the cyclic group generated by Z. 276
Table 7.2:
T h e two-generator oriented point
g r o u p s and their g e n e r a t o r s . Group
a
Group
a
2/m
i
[010]2
31m
3
1/m
i
4
122
4
6/m
i
222
2
mm2
2
321
3
312
3
3 ml
3
31m
3 3
3m1
(E7.45) Example:
(S
6
Qmm
4
[ioo]2
U2m
4
[100]m
4m2
4
622
6
6mm
6
[1C0] 2 [210]2 [100]m [210]m
62m
6
6m2
6
I [210] 2 [ioo]2 [ioo]m [100]2 [100]m [100] 2 i m
m
[100]2 noo]m
[100]2
Let a and (5 be the generators listed in Table 7.2 for
a two-generator point group.
Show that if
c P f
= 1,
then a" = 1 and f5m = 1 . Solution:
Suppose a n $ m = 1.
But g"7 £ and a B
m
n
t .
Then
Since tf" = -a", & m c
fl < a > -
7
B
y P7.44,
n
= 1 . Therefore, a^p" = 1 becomes a 1 = 1 and so a" = 1 .
(P7.45) Problem:
Show that, if a V = ak^m
1 < /, m < o(B) then /' = k and /' = m. that
{y,y J ,...,y o(y) }
•
where 1 < /, k < o(a) and
Use E7.45 together with the fact
are always distinct elements for any element of
finite order. (E7.46) Example: H = {aV
Use (7.29) to show that | /,/' e Z where 1 < /' < o(a) and 1 < / < o(3)}
where H is a two-generator point group and a and 3 are as defined in Table 7.2. 277
Solution:
We begin by showing that
K = {aW
| /,/ £ Z
where 1 < / < o(a) and 1 < /' < o(a)}
is a group.
Since K
show that K
is nonempty and closed under composition.
is nonempty. (a23) (a3
is contained in the finite group H,
we need only
Since a £ K,
K
To show that it is closed, we must show that elements like
) can be rewritten in the form a'fi'.
noting that since af5a = g, we have f5a = a
This is accomplished by Hence if we move a 3 from
the left side of an a to the right side we must replace a with a
This
is much like what we did in (7.24) to move the translations to the left. Hence, (a 2 g)(a 3 & 2 ) = a2f5aaaf$2 = a 2 a" 1 gaag 2 = a2«"1«"1^2 =
a V W ^ g
= .TV
•
Since a ^ £ a ^ = a' for some 1 < / < o(a). some
1 < / < o(i5).
(a^^)
(am(¡n)
1 < /' < o((3). by
Using
this
can be written
process,
in the
form
2
any
Similarly f53 = & for product
of
the
form
a'ft' where 1 < i < o(a) and
Hence K is a subgroup of H (recall that a, ¡5 e H) .
P7.45, the elements in K
Note that in each case in Table 7.2 (T7.47) Theorem:
= o(a)o(£>) and so H = K.
Let L denote a lattice left invariant by
generator point group H
But,
are all distinct and so #(/C) = o(a)o(P).
the
•
two-
and let a and 3 be as given in Table 7.2.
Let
P denote the basis for the primitive sublattice of L associated with H. Let Mj = Mp(a) and M 2 = Mp((5).
There exists a crystallographic space
group C satisfying (7.22) such that each element
of R ^ ^ ( G )
can
be
written in the form {I3 | V}{Mi | r}'{M2 | s>' where {I3 | v} £ Rp2,0]t are consistent with a1* = 1 , 3 2 = 1 and (S = af5a.
Solution:
Since o(a) = 4, o(g) = 2, Ni = Mi + M? + M? + M^ and N2 =
M 2 + M2.
Since
Mi =
0
-1
o'
1
0
0
0
0
1
and
"l
0
0
-1
0
0
0
-1
M2 =
o"
we have 0
0
0
0
0
0
0
0
4
and
N2 =
2
0
0
0
0
0
0
0
0
Since Njr = [001]1 and N 2 s = [100]1, by T7.33, r is consistent with a* = 1 and S is consistent with f$2 = 1 with respect to T p and P.
To show that
r and S are consistent with 3 = ceESa, we calculate the product
(M! | [ 0,0,3] t }{M 2
| [i,i,0]t}{M1
| [0,0,4]*} = {M2 I [-i,|,0] t } .
But {M, I ["Li,0] t } = {I, | [-l,0,0] t }{M 2 | [|,i,0]t} Since {I3
| [-1,0,0] ) e R p ( T p ) , r and s are consistent with B = aga with
respect to T p and P.
By T7.47, the set of matrices of the form
{I3 V £ Z3,
where
1 < i< 4
crystallographic 422.
space
I vKH, and
| r}'{M2 | s}'
1 < /' < 2
group C
,
represents
satisfying
the
elements
(7.22) where L = P
of
and H =
This space group is denoted P4 1 2 1 2.
(E7.49)
Example:
and L = P. Solution:
•
Find all of the space groups C derived from H =
321
Then determine all of the corresponding space group types.
By Table 7.2, a = 3 and g =
Then
0 - 1 0 Mi = M p (3) =
1 - 1 0 0
0
and 1
280
M2 =
a
M / ,(I
1, {M?M2 | [0,0,l/3]t}
283
Since 0
o"
1
It
1
0
0
0
0
-1
and
the general equivalent positions for P3221 [x.y.z] 1 ,
0
-1
2 MIM2 =
o"
-1
1
0
0
0
-1
are
(2/3) + z] t , [y - x , - x , (1/3) + z ] \
[-y,x - y,
- y , - y , -z]*-, [y, x, (2/3) - z] t , [-x, y - x, (1/3) - z]* (P7.46)
Problem:
The
ITFC
equivalent positions for
[*, y . I}1, [y,x,-z]\
c
1983) gives the following general
P3221:
l-y, X - y,
(2/3) + z ] \
[y - x, - x , (1/3) + z] 1 ,
[x - y , - y , (1/3) - z]*, [-x, y - x,
that if we move our origin to p =
Show {M 2
(Hahn,
.
[ 0 , 0 , ,
(2/3) -
z
.
then {Mi | r}
and
I s} are changed so that the general equivalent positions as given
in the ITFC are obtained. (P7.47) Problem: e
P ti212
Determine the principal representatives of space group
(E7.48) and confirm that its general equivalent positions are:
[*> y , z] 1 . l-y, x, 4 + [y, - x , (3/4) + z]1, [-i (P7.48)
y - i, i Problem:
[-*, - y , i +
[i + x, i - y, - z ] \ [i - y . -i - *>
The ITFC (Hahn,
equivalent positions for
1983)
z^, [y - i, \ + x, i - z ] \ (3/4) - z] t
gives
the
.
following
general
P4l212:
[x, y, ¿I 1 , [-*, - y , i +
[i - y, i +
i +
t
[i + y , i ~ x,
(3/4) + z] , [1 - X , i + y, i - z]fc,
li + X , i - y,
(3/4) - z]*,
[y, X, - z ] 1 , [-y, - x , i - z]* .
Find p such that if our origin is moved to p , these general equivalent positions occur.
(E7.51) Example: P3221
An element of the right coset R p ( T p ) { H 2
is of the form 284
| [000] 1 } of
1
u
1 - 1
0
V
0 - 1
1
w
0
0
1
0
0
0
0
1
0
0
0
0
0
0
1-1
0
0
o-i
0
U
o
v
0 - 1 0
0
0
-1
W
0
0
0
0
0
1
where, because the lattice is primitive, u, v, W e Z.
1
Analyze the matrix
on the right, using the techniques discussed by Boisen and Gibbs (1978) and determine the name of the space group operation a that it represents and a point on its symmetry element. Solution:
As tr(M 2 ) = -1 and det(M2) = +1, we know that the linear part
of a defines a half-turn. [100],
We also know that its rotation axis parallels
The translational component, d, of a is found by solving d = i I Mjt = ¿(M2t + Mjt) /'=1
where t = [i/,v,w]
and so
/"l
-1
d = i| 0 0
V
,
0
u
-1
0
V
0
-1
Hence, a =
"l +
w
0
o'
0
1
0
V
0
0
1
w
\
u
/
u
-
v/2~
0
=
0
modulo the translation group when v is odd and a =
[100]2 modulo the translation group when v is even. The set of points defining the symmetry element of a is found using the equation t - d = (I, - M 2 )e where e = [e 1 ,e 2 ,e 3 ]
u V
u
-
denotes a point on the rotation axis of a.
w
=
0
'
1
0
o'
0
1
0
0
0
1
v / 2 ~
0
-
0
V / 2 ' V
w
=
1 0
0
2
0
0
0
2
285
-
"l -1
0
0
-1
0
0
0
-1
\
I
e2 ,