ISBN: 0-471-25620-X

Текст
                    INFRARED AND RAMAN
SELECTION RULES
FOR MOLECULAR AND
LATTICE VIBRATIONS
The Correlation Method


Infrared and Raman Selection Rules for Molecular and Lattice Vibrations: The Correlation Method William G. Fateley and Francis R. Dollish MELLON INSTITUTE PITTSBURGH, PENNSYLVANIA Neil T. McDevitt and Freeman F. Bentley AIR FORGE MATERIALS LABORATORY () WRIGHT-PATTERSON AIR FORGE BASE, OHIO WILEY-INTERSGIENCE, A DIVISION OF JOHN WILEY & SONS, ING. NEW YORK ' LONDON • SYDNEY . TORONTO
Copyright © 1972, by John Wiley & Sons, Inc. All rights reserved. Published simultaneously in Canada. No part of this book may be reproduced by any means, nor transmitted, nor translated into a machine language without the written permission of the publisher. Library of Congress Cataloging in Publication Data: Main entry under title: Infrared and Raman selection rules for molecular and lattice vibrations. 1. Crystal lattices. 2. Vibrational spectra. 3. Representations of groups. I. Fateley, William G. QD921.148 548'.81 72-4120 ISBN 0-471-25620-X Printed in the United States of America 10-9 8 7 6 5 4 3 2 1
INFRARED AND RAMAN SELECTION RULES FOR MOLECULAR AND LATTICE VIBRATIONS The Correlation Method
PREFACE The application and development of the correlation theorem presented in this book grew out of conversations with Prof^or James R. Durig at a NATO Meeting on the Solid Sta/^ ^id m Delft, Holland, in 1968. At that time we were only frnidly interested in the derivation of selection rules for molecul?jr vibrations in solids. However, we found the application of the correlation theorem of group theory, as suggested in the original papers by Halford and Hornig, quite an enjoyable J&sk and certainly a time-saving, foolproof method for generating selection rules for crystals. A seminar on this subject given that fall encouraged us to write down some practical rvtfes for the application of this method to various crystals. As w,^ became more adventurous in our studies of crystals, we found, xo our amazement, that the application of the correlation method was incorrectly applied to a number of crystals reported in the literature. The main difficulty seemed to be the improper choice of a correlation table relating the site group to the factor group. Wishing to remove this obstacle, we constructed a table that now provides the correct correlation for each site whenever choices exist. We have attempted to present adequate examples so that the reader- may better understand this method and to provide a number of shortcuts that reduce this compilation to only a few minutes work.
vi Preface An outgrowth of this effort was the construction of general tables for the vibrational selection rules in molecules. Certainly Herzberg's excellent book, Molecular Spectra and Molecular Structure, Vol. II, Infrared and Raman Spectra of Polyatomic Molecules, provided many of these tables. Herzberg does not provide tables for all the molecular point groups that are physically possible; therefore we decided to extend them. In the tables presented here we have identified the sets of equivalent atoms present in molecules by their site symmetries. This approach is consistent with the method used in crystals. We have not attempted to predict the selection rules for nonrigid molecules and for crystals beyond the boundary k — 0 of the Brillouin zone, but, we are sure that the reader can make this extension with the proper application of the more expanded double groups and group theory. Even though we are only applying well-known principles of the correlation theorem in group theory according to the rules provided by Halford and Hornig, we continue to find new enjoyment inlhJ '?c1xT'^vat^on °f these selection rules. We hope you will. We should like to acknowledge many helpful discussions with Dr. Gerald L. NG5rJson? Mr. Peter Larsen, Professor William White, Professor Coln7, Farmer, and Professor F. A. Miller. We wish to thank Carolyn Ke*1' f°r ner patience in translating and typing our illegible chicken ti^cks into a manuscript. One of us, William G. Fateley, wishes to acknowledge partial support from an unrestricted grant provided by the Gulf ^search and Development Foundation. We also greatly appreciate the partial financial support received from the Mellon Institute\of Science of Carnegie- Mellon University and from Air Force Contract No. F 33 615-70- 1382. Willia^. G. Fateley* Francis R.. Dollish Neil T. McDevitt Freeman F. Bentley Pittsburgh, Pennsylvania Wright-Patterson Air Force Base, Ohio February 1972 * Present address: Head, Department of Chemistry, Kansas State University, Manhattan, Kansas 66502
CONTENTS CHAPTER 1 PRACTICAL METHODS FOR SELECTION RULES 1 CHAPTER 2 SITE SYMMETRY AND CORRELATION TABLES 35 CHAPTER 3 THE BHAGAVANTAM AND VENKATARAYUDU METHOD 53 CHAPTER 4 MOLECULAR SELECTION RULES 65 CHAPTER 5 APPLICATION AND SPECIAL CASES 117 APPENDIX I SITE SYMMETRY TABLE FOR THE BRAVAIS SPACE CELL 171 APPENDIX II CHARACTER TABLES 181 APPENDIX III CORRELATION TABLES 201 INDEX 217 vii
CHAPTER ONE PRACTICAL METHODS FOR SELECTION RULES With the recent increase in interest in infrared and Raman spectra of crystals, it has become important to determine which vibrational modes are optically active. Hornig [1], Winston and Halford [2], and Bhagavantam and Venkatarayudu [3] pioneered in developing methods for solid-state selection rules. Heretofore the application of these rules has been a laborious procedure fraught with difficulty and with many points of indecision. Among the latter is the choice of the primitive cell and the correct site symmetry of each atom. What is needed is a short, straightforward, foolproof method. In this book we have outlined some practical rules for the use of the correlation Pages 1 to 42 of this book originally appeared as "Infrared and Raman Selection Rules for Lattice Vibrations: The Correlation Method," by W. G. Fateley, Neil T. McDevitt, and Freeman F. Bentley, Applied Spectroscopy, 25, No. 2, 155-173 (March/April, 1971).
2 Practical Methods for Selection Rules method to derive the vibrational selection rules for both crystals and molecules. These practical rules reduce the calculation to only a few minutes work. The correlation procedure which has already been discussed in several papers and books dealing with lattice vibrations [2-5], is explained in detail by the use of numerous examples. We have chosen not to review the theory but to proceed directly to a demonstration of its use, and that of the correlation tables, to obtain the vibrational selection rules for solids. An orderly procedure is outlined for the step-by-step calculation of selection rules that will predict infrared and Raman activity. The reader is warned that there may be slight variations in some of the steps used in this method, but intelligent reasoning will help him to overcome them. 1. CRYSTAL STRUCTURE The crystal structure of the sample must be known. Alternatively, a structure can be assumed and predictions made for the vibrations, which can then be compared with observations to prove or disprove the assumed structure. It is far better, however, to know the structure in advance. Crystallographic information may be obtained from Refs. 7 and 8 or from the original literature. Examples of the data needed are given in Table 1. 2- MOLECULES PER BRAVAIS SPACE CELL The Bravais space cell is used by molecular spectroscopists to obtain the irreducible representation for the lattice vibrations. The crystallographic unit cell may be identical with the Bravais cell or it may be larger by some simple multiple. This can be ascertained from the capital letter in the x-ray symbol for the crystal structure. For all crystal structures designated by
2. Molecules Per Bravais Space Cell TABLE 1 Crystallographic Information for Several Examples Crystal structure nomenclature [7, 8] Crystal Molecules Lattice Molecules per per unit points [5] Bravais cell, -" (Z/LP) per unit points [5] Br; X-Ray Spectroscopic cell (Z) [7,8] (LP) ZB SrTiO3 TiO2 (anatase) ZrO2 a-Al2O3 Cu2O NH4Ia P2i/c /to/. p P 1 4 4 2 2 ■ 2 1 2 1 1 1 1 a Phase III [6]. a symbol containing P (for primitive) the crystallographic unit cell and the Bravais unit cell are identical. (An example from Table 1 is Pm2m for SrTiO3.) Crystal structures designated by other capital letters (B, C, /, etc.) have crystallographic unit cells that contain two, three, or four Bravais cells. (An example from Table 1 is I& /amd for TiO2.) The irreducible representations obtained from these crystallographic unit cells will contain two, three, or four times as many vibrations as are needed to represent the lattice vibrations of the crystal. This problem of including too many Bravais cells in the crystallographic cell can be eliminated by dividing the number of molecules per unit crystallographic cell by a small integer which is identical to the number of lattice points (LP) in a crystallographic cell of specific symmetry, as designated by the capital letter in its symbol. Table 2 gives this number (LP) which reduces the size of the crystallographic unit cell to the desired Bravais space cell. This reduction has been included in Table 1. In summary number of molecules in the Bravais space = cell number of molecules in Z crystallographic unit cell (LP) number of lattice points (from table 2)
Practical Methods for Selection Rules TABLE 2 The Number (LP) that Reduces the Crystallographic Unit Cell to the Bravais Space Cell Type of crystal structure A B C F I P R Number (LP) 2 2 2 4 2 1 3 or la a Here the crystallographic group may have already been decreased by three; if so, the crystallographic cell need not be divided. A simple indication whether to divide by three is found in the example of a-Al2O3 (Table 1) which contains two molecules per unit cell. Certainly we should not divide by three in this case. 3. SITE SYMMETRY OF EACH ATOM IN THE BRAVAIS CELL The equilibrium position of each atom lies on a site that has its own symmetry. This site symmetry, a subgroup of the full symmetry of the Bravais unit cell, must be ascertained correctly for each atom. It is easy to do so in some cases, difficult in others. Let us consider the following examples. Cu2O Table 1 states that the symmetry is 0\ and that there are two Cu2O units in a Bravais cell. There are therefore four equivalent
3. Site Symmetry of Each Atom in the Bravais Cell 5 copper atoms and two equivalent oxygen atoms in the Bravais unit cell.* Next we turn to the table in Appendix I (p. 179) and look for the entry 0* in the third column. It is number 224. In the right-hand column all the possible site symmetries for this space group are tabulated. They are written as 7^B), 2D3(fD), ZJdF), . . . , and are given in full in Table 3. They represent all the possible kinds of site for an 0* crystal, but most of them will not be occupied in a specific crystal. TABLE 3 Site Symmetries for the Space Group Designated O\ or Pn3m or 224 (Cu2O) Bravais cell site symmetry TdB) 3(il / X/ O/f v ^ / C3 (8) X)aA2) 3C2B4) C.B4) CiD8) Number of equivalent atoms accommodated on this site of Bravais cell (number in parentheses) 2 4 6 8 12 12 24 24 48 Number of kinds of sites of this symmetry (the coefficient of column 1) 1 2 1 1 1 1 3 1 a a No coefficient is needed because there are an infinite number of Cx sites. The most useful information is the number contained in parentheses, for it represents the number of equivalent atoms which have that particular site symmetry; for example, TdB) indicates that there are two equivalent atoms occupying sites of * This rule is always applicable, provided that the equivalent atoms have been found in a crystallographic cell. This information is provided with the crystallo- graphic structure in Refs. 7 and 8 (p. 170).
6 Practical Methods for Selection Rules symmetry Td; similarly, D3dD) indicates the presence of four equivalent atoms on DZd sites. Some of the site symmetries have numerical coefficients, such as 2ZKdD) in Table 3. The coefficient 2 shows the presence of two different and distinct kinds of DZd site in this unit cell. Each can accommodate four equivalent atoms. In a given crystal there may be atoms on one or both sites or on neither. The second and third columns of Table 3 illustrate these remarks. For Cu2O the x-ray results show four equivalent copper atoms and two equivalent oxygen atoms. What will be their site symmetries? From Table 3 (or from the equivalent entry in Appendix I, p. 179) we see that only one site symmetry can accommodate four equivalent atoms—ZKd. Therefore the site symmetry for copper is DZd. Similarly, only one kind of site can accommodate just two equivalent atoms—Td. This therefore is the site symmetry for oxygen. (Note. When selecting the site symmetry, we must always have the number of equivalent atoms equal to the accommodational value of the site symmetry.) The above example was atypically simple in that there is no ambiguity in the result. We turn now to another example that is slightly more difficult. TiO2 (Anatase) Table 1 shows us that the space group is designated DH or /4 /amd9 with two molecules per Bravais unit cell. There are therefore two equivalent titanium atoms and four equivalent oxygen atoms in this Bravais cell. From Appendix I (p. 176) we find that this is spacegroup number 141 which has the site symmetries 2D2aB), 2C2ftD), Ct,D), 2C2(8), C.(8), and ^A6). Consider first the two equivalent titanium atoms. Only the D2d sites accommodate two atoms; therefore it follows directly that the titanium atoms are on sites of D2d symmetry. There are two separate kinds of site (coefficient 2), but it is not necessary for us to know which kind is occupied.
4. Correlation of the Site Group to the Factor Group 7 For the four equivalent oxygen atoms there are two possible site symmetries—Cih and C2v; both will accommodate four equivalent atoms. One or the other will be correct, but additional information is needed to make the choice. For this we turn again to the crystallographic tables [7, 8], which state that the oxygen atoms lie on C2v sites. (See Chapter 2 for an explanation of the use of crystallographic tables.) This additional information is needed whenever we meet an ambiguity of this kind. Table 4 lists the site symmetry of each atom in the various examples used in this chapter. TABLE 4 Site Symmetry of Each Atom in Various Examples TiO2, Example: anatase SrTiO3, Cu2O a-Al2O3, ZrO23 NH4I Site of Ti-Z>2d Sr-(\ Cu-D3d Al-C3 Zr-Cx NH4-Z>2d equivalent O-C2v Ti-O,, O-Td O-C2 O-Q I-C4v atoms O-D^h 4. CORRELATION OF THE SITE GROUP TO THE FACTOR GROUP* The site symmetry for each atom in the lattice has already been found and the results are summarized in Table 4. The symmetry species are now identified for each equivalent set of atom displacements in the site. The displacements we describe will become the lattice vibrations in the crystal. Knowing the site species for these displacements, we find that the correlation tables, which appear in Appendix III (p. 201), relate each * Note. Different authors vary in their choice of the term factor group, crystal group, or correlation group to describe crystal symmetry. These terms are equivalent.
8 Practical Methods for Selection Rules species of site group to a species of the factor group. This correlation explicitly identifies the species of the lattice vibration in the crystal and further allows prediction of infrared or Raman activity. Using the following molecules as examples, we first identify the lattice modes in the crystal by obtaining the irreducible representation that contains the number and species of the lattice vibrations, and second, we describe the infrared and Raman activity of each vibration. TiO2 Crystal As summarized in Table 4, the two titanium atoms are in D2d sites and the four oxygen atoms are in C2v sites. In this example each set of equivalent atoms is treated separately. Titanium Atoms First, the vibrational displacements of the titanium atoms in the lattice can be described as simple motions parallel to the x, y> or z axis. This simplified description of vibrational mode allows easy classification into one of the species of the site symmetry—D2d; for example, the displacements of the titanium atoms parallel to the z axis will have the same character as the translation in the z direction. The translation Tz belongs to the species B2 of the site group. Therefore the atom displacements parallel to the z axis will also belong to the Bz species. Similarly, the displacements of titanium atoms along the x axis will have the same character as Tx and will belong to species E. It is important to note here that this approach, which classifies the lattice vibrations as excursions in x,yy and z directions, is no different from the descriptions used for molecular vibrations such as bond stretching, bending, and twisting. Of course, normal vibrations in a crystal or a molecule are far more complex than this simple displacement picture provides; however, the importance of this method is found in the simplicity with which the lattice vibrations can be classified.
4. Correlation of the Site Group to the Factor Group 9 When the species of the site group is identified for each excursion of an equivalent set of atoms, this information is integrated via the correlation tables to the species of the crystal that contain this lattice vibration. To begin this correlation procedure Table 5 lists a portion of the D2d site group and identifies the species of the translations TX9 Tv, and Tz; see Appendix II (p. 183) for character tables. Since the lattice vibrations have TABLE 5 Species of the Site Group D2d and the Translations D2d site of titanium atom species Translation species Ti atoms excursion Motions parallel to z axis Motions parallel to x andjy axes the same character as the translations, the species that contain these vibrations can readily be identified and this information is presented in Table 5. Before applying the correlations of site to factor group we define some useful terms to help in the practical application of this method. 1. ty = the number of translations in a site species y. This number can take the value of zero, one, two, or three, depending on whether none, one, two, or three translations are contained in the site species y, respectively. This information is readily available from the character table in Appendix II (p. 181). Ry = the number of rotations included in the site species y. Again this value will be zero, one, two, or three. The character tables in Appendix II clearly identify the rotations as Rx, Ry, and Rz.
10 Practical Methods for Selection Rules 2. fy = degrees of vibrational freedom present in each site species y for an equivalent set of atoms, ions, or molecules. This can be calculated as follows, where n is the number of atoms (ions or molecules) in an equivalent set: fyR = degrees of rotational freedom present in each species y for an equivalent set of ions or molecules. This can be calculated by modifying A) to give fk = Ry ■ n O) 3. ay represents the degrees of freedom contributed by each site species y to a factor group species £. The value of ay can be calculated as follows: B) The derivation of this equation is not presented here; however, it is stated in B) that the degrees of freedom in the site are equal to the degrees of freedom in the factor group for each equivalent set of atoms, ions, or molecules. 4. Q = the degeneracy of the species £ of the factor group. An additional superscript y may sometimes be added to show its correlation to a species of the site group. The usual values of Cc are summarized in tabular form on the facing page. There are exceptions to this description of degeneracy for certain correlations in which separable degeneracy exists. Without a proof the following modification to the existing
4. Correlation of the Site Group to the Factor Group 11 Speciesa Value of C^ A 1 B 1 E 2 F 3 G 4 H 5 a Usually the species designation has a superscript, e.g., A\ A", or a subscript, e.g., Alsp Eg, Flu; however, these super- and subscripts in no way describe the degeneracy of the species and for this reason are not included here. correlation tables, Appendix III (p. 201), gives the correct correlation and ay values: 1. Point group C6, C8ft, C4ft, C5h, CQh, S6, T, and Th do not use the 2 coefficient which appears in these correlation tables for the doubly degenerate Et species. These elements, found in Appendix III, are marked with an asterisk (*) to indicate the necessity for dropping the 2 coefficient. 2. Only a portion of the T and Th point group correlation tables is given; however, the table must be modified as follows: F A + 2E Fg Ag + 2Eg A + 2E Fu Au + 2EU A + 2E Here a coefficient of 2 is added to the E species which must be doubled because of the separable degeneracy. A double dagger ($) is used in the table in Appendix III to call
12 Practical Methods for Selection Rules attention to those entries in which a 2 coefficient must be added to the Ei entry of the table. convenient ghegks. It is helpful to check the bookkeeping as the correlation method progresses. The following equation, when applied, will help to avoid errors. 3n = (degree of freedom) sifce = 2 fy C) V Zn = (degree of freedom)facfcorgroup = £ HCl D) where a^ = ]Ty S and -W ^s the total number of atoms in the Bravais cell; i.e., N = 2eq sets n- The irreducible representation of the crystal gives the number of lattice vibrations in each species of the factor group. The total irreducible representation of the crystal, rcrysfc, is the combined irreducible representation of each equivalent set of atoms, reqsefc [see G)]. The Peq set is constructed in the following manner: Teq set = 2 aC ' £ (^) C where a^ as previously defined, is the number of lattice vibrations of the equivalent set of atoms in species f of the factor group. The total irreducible representation of the crystal, Fcryst, can be constructed as follows: pcryst p , -p , /c\ 1 — L eq set 1 T~ -1 eq set 2 "T" V°7 This irreducible representation of Pcryst contains the acoustical vibrations. In the following examples these vibrations are removed from this representation by simply substracting out the irreducible representation of the acoustical vibrations: pcryst _ pcryst pacoust /j\
4. Correlation of the Site Group to the Factor Group 13 Now F^st is the irreducible representation of the lattice vibrations in the crystal. This procedure needs only minor modification to include the intramolecular vibrations and librations for molecular crystals. Here the irreducible representation of a molecular crystal can be defined as rmol cryst -pcryst . t-i i T1 "pacoust /o\ vib — -»■ vib "T 1 mol vib ~r 1 lib ~~ L \fi) TABLE 6 Titanium Atoms on Site D2d. The Degrees of Vibrational Freedom for Each Species (n = 2 atoms/eq set) Degree of vibrational freedom D2d species Translation ty fy = n • t7 E 0 0 0 1 2 0 0 0 2 4 The molecular crystal NH4I (p. 25) demonstrates the usefulness of (8). Utilizing the above definition, we list in Table 6 the degrees of vibrational freedom for each species of the site group D2d for the equivalent set of titanium atoms. Table 6 indicates the presence of the titanium lattice vibrations designated as degrees of freedom in species Bz and E. The next step is to correlate the B% and E species of the site group D2d to the ZL7l factor group species. The correlation tables are given in Chapter 2 for D2d to D^ and are also presented in Refs. 10 and 11.
14 Practical Methods for Selection Rules By extracting only a portion of these correlation tables in Chapter 2 (p. 42) we find the following relationship between the site and factor group species: site group species A* factor group species A complete set of correlation tables needed in this procedure appears in Appendix III (p. 201). We have chosen to present in Chapter 2 (p. 42) two specific tables to show primarily how they are derived and to provide the proper basis for selection of the correct correlation ta.bles when two or more possibilities exist. Since only the site species B2 and E contain these translations, which are like the lattice vibrations in the crystal, the correlations relating these species to those in this factor group are of immediate interest. By integrating the site species which contain the translations into the factor group by use of the correlation tables it is easy to identify these lattice vibrations in the factor group species. Table 7 shows this correlation and identifies the species of the lattice vibration in the crystal.
4. Correlation of the Site Group to the Factor Group 15 TABLE 7 The Correlation for the Lattice Vibrations of the Titanium Atoms in TiO2 Crystal Between The Site Group D2d and Factor Group D4A f D2d site species, y correlation DAh factor group ay species, £ Q a$ — aB + a2 1 1=1 1 1 = 2 1 = 2 } 1 0 0 1 The titanium atom's irreducible representation for the factor group is obtainable with Equation 5: V = ^ a^ • £, where #c = 2y av i-e-> ^e number of vibrations in species £. Therefore the species of the factor group that contains lattice vibration involving the titanium atom can be written as the following irreducible representation FTi. - 1 • Blg + 1 • A2u + 1 - Eg + 1 • Eu. A check can be made at this point for possible errors by utilizing Equations 3 and 4. Equation 3: Degrees of vibrational freedom of equivalent Ti atoms in site = 3n = 6 = %yfy = 6. Equation 4: Degrees of vibrational freedom of equivalent Ti atoms in factor group = 3rc, where 2C aft = 1 + 1 + 2 + 2 - 6 = 3n for n = 2.
16 Practical Methods for Selection Rules Oxygen Atoms By following the same procedure we can obtain the irreducible representation Foxy for the equivalent set of oxygen atoms. A summary of the necessary information is given in Table 8. TABLE 8 Tabulations of Terms and Correlations Necessary to Calculate the Lattice Vibrations of the Oxygen Atom in TiO2 Crystal C2v site fy ty species, y correlation D4h factor species. = aAl + aBl + aB% 4 1 (Tz)Ai 4 1 (Tx, 4 1 1 1 1 0 1 1 1 0 2 2 1 0 1 1 1 0 1 1 2 2 + 0 + +0 + + 0 + = 0 + 1 + 1 = 0 + 0 + 0 = 1+0 + 0 = 0 + 0 + 0 1 0 + o + + 1 + CHECKS Equation 3: = Zn = degrees of freedom for >the equivalent set of Equation 4: 2 acQ = ^n = 12 I oxygen atoms. The number and species of oxygen lattice vibrations can now be calculated for Foxy = = 2 H • £ = 0Alu + IA 2U 0B2g 0Blu 2E9 \B 2u 2EU
4. Correlation of the Site Group to the Factor Group 17 COLLECTING TERMS roxy = Alg + Blg + 2Eg + A2u + B2u + 2EU The total representation of the crystal, rcryst, can be calculated by utilizing Equation 6, where rcryst is the sum of the individual irreducible representation for each set of equivalent atoms, or rcryst = rTi + roxy, + (Alg + Blg + 2Eg + Aiu + B2u + 2EU) = Al9 + 2A2u + 2Blg + B2u + 3Eg + 3EU Applying a check at this point on the vibrational degree of freedom, we find that Equation 4 gives 3N = ^ eqsets a? • C?, where N is the number of atoms in the Bravais cell for TiO2 N = 6. Therefore 3 • N = 18 = WAig + 2CMu + 2CBig + \CBu + 3CEa + 3CEa The acoustical vibrations are included in the irreducible representation, rTi°2 cryst, given above. Of the 3N degrees of vibrational freedom, three of these vibrations are acoustical modes. When we consider only those vibrations at the center of the Brillouin zone, i.e., k ^ 0, the three acoustical vibrations have nearly zero frequency. Since vibrations with zero frequency are of no physical interest here, these acoustical vibrations can be substracted from the irreducible representation as suggested in Equation 7: rcryst -pcryst -pacoust vib = 1 — 1 The acoustical modes are readily identifiable in factor groups, since they have the same character as the translation; Table 9 shows this identification.
18 Practical Methods for Selection Rules TABLE 9 D47i Factor Group, Translation and Acoustical Modes Translation Acoustical mode D^h speciesa species species Eu Tx.y V a See Appendix II (p. 188) for D±h point group. Therefore the irreducible representation of the acoustical vibrations racoust = AZu + Eu. The results of this factor group analysis, which identifies the number of lattice vibrations in each species and the spectral activity, are summarized in Table 10. Table 10 gives the following selection rules for first-order Raman and infrared activity in the TiO2 crystal: raman spectrum : Six fundamental lattice vibrations allowed one Algy two Blg, and three degenerate infrared spegtrum: Three fundamental lattice vibrations allowed one A2u and two degenerate Eu. One vibration, B2u, will be inactive in both the infrared and the Raman spectrum. Also, there will be no coincidences, i.e., the same vibration mode which is active and observable by both the Raman effect and in the infrared spectrum. This completes the original goal of obtaining (a) the number of lattice vibrations in TiO2 (anatase) and (b) the spectral activity of these vibrations. Additional information may be had by studying the polarization properties of Raman scattering. This procedure, however, is not discussed here. SrTiO3 Crystal Now that the step-by-step procedure has been applied to obtain the molecular vibrations and activity for TiO2 crystal,
TABLE 10 D4h Factor Group Species, Translations, Acoustical Modes, Number of Lattice Vibrations and Infrared and Raman Activity of TiO2 Crystal, Anatase Raman D^h factor Translation Acoustical rTi°2 cryst T™2 Infrared polarization Raman group species species mode species coefficients coefficientsa activityb tensor species activity0 Air * * i&xx + Kyy)) &ZZ V Bxl 2 2 (axx - <zyy) V B a a/ Eg 3 3 **™*,* V Au Tz 1 2 1 V B2\ 1 1 Eu TXtV 1 3 2 V a pTiO2 __ pcryst TiO2 pacoust V'b = (Alg + 2A2u + 2Blg + B2u + 3Eg + 3EU) - (A2u + EJ — Alg + A2u + 2Blg + B2u + 3Eg + 2EU. These coefficients are the number of lattice vibrations present in the species. b Only those species that contain the translations are infrared active; i.e., A2u and Eu are the only species that have infrared active vibrations (see Appendix II, p. 188). c Those species that contain the polarizability tensor can have Raman activity; i.e., Alg> Blg, B2g, and Eg can have Raman active lattice vibrations. This information is readily available from Appendix II.
20 Practical Methods for Selection Rules there are several short cuts which, when applied, reduce the calculation to only a few minutes. SrTiO3 crystal serves as an example for this simplified procedure. INFORMATION crystal: SrTiO3, PmZm-Oxh, ZB = 1 (seeTable 1). equivalent atom site: Sr-On(n = 1); Ti-Oh (n = 1); oxy- atoms — Dih {n — 3) (see Table 4). Irreducible representation of each equivalent set of atoms: STRONTIUM 3 3(T Therefore TITANIUM r f Q Q / rj-i > \ X 1/ Z 0h site symmetry species containing translation ) Flu c 0h site symmetry species containing translation ) F ' r Lu correlation nr - Y = 1 • F correlation 0h factor group species Flu tu 0h factor group species F Q 3 3 1 1 Summary:
4. Correlation of the Site Group to the Factor Group 21 OXYGEN f D±h site symmetry species containing translation correlation 0h factor group species = aA%u + a Eu 3 1G* 6 2G* z) ^2w ■*■ oxy == A acoust — 77 ^_ rlu F2u Flu F2u> m) 3 3 o j 1 0 + + 1 1 Summary : pSrTiO2 1 cryst vib _j_ p i p p Sr "T -1 Ti ~T ■»- oxy -1- acoust i« + F2u) The 0A character tables, Appendix II (p. 198), identify Flu as infrared active and F2u as neither infrared nor Raman active. Therefore SiTiO3 has three infrared active fundamental vibrations and no first-order Raman spectrum. In Chapter 3 (p. 64) is an identical irreducible representation by a different, more laborious method. Cu2O Crystal information: 0%-Pn3m9 ZB = 2 (see Table 1). equivalent atom-site: Cu-DM (n = 4); oxy-Td (n = 2) (see Table 4).
22 Practical Methods for Selection Rules Irreducible representation of each equivalent set of atoms: COPPER f D3d site symmetry species containing translation correlation 0h factor group species Q = aA + a Eu 4 1(TM) 8 2(TM) 1 1 2 1 3 2 3 1 1 + 0 0 + 1 1 + 1 0 + 1 OXYGEN 2u f Td site symmetry species containing translation correlation 0h factor group species Q P acoust — •* lu Irreducible representation of the crystal pCuaO p i p p -1- vib — x Cu ~r x oxy L acoust = (A2u +EU+ 2Flu + F2u) + (Flu = AZu +EU+ 2Flu 2u F2g. - (Flu) Spectral activity: Raman — Fig; infrared — Flu
4. Correlation of the Site Group to the Factor Group 23 Therefore there will be one triply degenerate fundamental lattice vibration (F2g) active in the Raman effect and two triply degenerate infrared active lattice vibrations (Flu). A12O3 Crystal information : RZc-D\d:> ZB = 2 (see Table 1). equivalent atom-site: Al-C3 (n = 4); oxy-C2 (n = 6) (see Table 4 and Chapter 2). ALUMINUM Cz site symmetry correlation ^ r species —: >- DZd factor containing group ay fy ty translation species Q a^ = aA + aE \{TZ) A^__ Alg 1 1 = 1 + 0 1 1 = 1+0 8 2G; y) E--- ^<^^c ~E* 2 2-0 + 2 1 1 = 1 + 0 1 1 = 1+0 2 2 = 0 + 2 Here we observe that aA and aE have different values. Reviewing Equation 3, fy = ay 2/Q gives the values of ay. The dyS are evaluated in the following manner: Site species A: fA = 4 = aA{CAu + CAu + CAlu + CAJ = aAD); .: aA = 1 Site species E: fE = 8 = aE(CEs + CBu) = aEB + 2); /. aE = 2 Then
24 OXYGEN Practical Methods for Selection Rules f C2 site symmetry species containing translation DZd factor group species 12 A A, 1 0 1 1 0 1 0 2 2 0 2 2 r0xy = -di, + 2AZg + 3Eg + Alu + 2A2u + SEU J- acoust ^ ^2w "f" -^it Summary: Equations 7 and 8 give W» = (^l9 + A2g + Alu + A2u + 2Eg + 2Ea) + (Alg + 2A2g + 3Eg + Alu + 2A2u + 3EU) . - (A2u + Eu) r*}|p. = 2A%* + 3iC + 2Ji°' + 2A£?} + 5E™ + ZrO2 information: P2 -C\h, ZB = 4 (see Table 1). equivalent atom site : Zr-Q (re = 4); oxy-Cj (n = 8) (see Table 3). * Here we can indicate the activity of each species by a superscript: (R) = Raman active; (IR) = infrared active; @) = inactive. This information is available from the character tables, Appendix II (p. 185).
4. Correlation of the Site Group to the Factor Group 25 ZIRCONIUM f Cx site symmetry species containing translation correlation C2h factor > group symmetry 12 1 3 1 3 1 3 1 3 OXYGEN Zr = 3Ag + 3Bg + 3AU 3BU fi Cx site symmetry species containing translation correlation C2h factor group symmetry 24 1 6 1 6 1 6 1 6 Summary: r0xy = QAg + 6Bg •*• acoust = A-u ~f" ^u 6BU 92?iR> NH4I Crystal (phase III) Durig and co-workers have made extensive investigations of the molecular crystal NH4I [6]. This crystal not only possesses lattice vibration but also libration and intramolecular vibrations of the NH^ group in the crystal. It is worthwhile to
26 Practical Methods for Selection Rules repeat Durig's calculations, with some modifications, to demonstrate the usefulness of the correlation method when applied to a molecular crystal. A natural division in applying the correlation method to a molecular crystal can be made as follows: 1. Derive the lattice vibration of the NHj ions and iodine ions. 2. Calculate the libration, i.e., rotation, of the NH+ group in the crystal. 3. Use the correlation technique to predict the number of intramolecular vibrations of the NH^ group. * By combining the irreducible representation obtained from Parts 1, 2, and 3 and using Equation 8, the total representation for NH4I is constructed. Lattice vibrations of NHJ Ion and Iodine Atom NH+ Ion information: NHJ, site Du, ZB = 2 (see Table 4). Du site symmetry species D±h factor containing correlation group li £ i fy ty translation c£ species Q ay = aE + a B% 4 2(T_) E === £„ 2 110 2 1 1 0 2 1G7) #*:=zr £,„ 110 1 110 1 The results are Cf2 -> C'l; the correlation is given in Table 11. t~\ 7)(R) | yi(IR) I lyxR) I TT'dR) * The lattice vibrations are sometimes referred to as external vibrations; the molecular vibrations within a crystal are called internal vibrations.
4. Correlation of the Site Group to the Factor Group 27 This correlation applies to the tables derived in Chapter 2 (p. 40). By repeating a portion of this table we realize that there are two possible correlations of D2d into D^hy as given in Table 11. TABLE 11 The Two Possible Correlations for D2d into D^ A) B) Factor group C2 -> C2 B2 Bx E E E E Correlation B) Cfz ~> C'l in Table 11 was correctly used in the above calculation, but what would the results be if the incorrect correlation B) Cz -> C'% were used ? Repeating this calculation but using the other correlation given in Table 11 which maps D2d——~D4h, we obtain D2d site symmetry species DAh factor containing correlation group li f\ i fy ty translation °f%^c\ species Q a^ = aE + a 2 1 = 1 + 0 2 1 = 1 + 0 11=0+1
28 Practical Methods for Selection Rules A summary of C'% -> C'z correlation gives •p z?<R> i jdR) i z?(R) i r^lR) Compared with the first calculation, C'2 -> C'l correlation gives -p n(R) , (IR) (R) (IR) A NHj" = -Big ~T j Both irreducible representations predict two infrared and two Raman-active fundamental vibrations. In this specific instance TABLE 12a NH^ Lattice Vibrations Correlation Correlation Polarizability tensor Ca -» Cl Cg -* C2 (Appendix II) 7? 77" /v /v a The result of the use of two different correlations from Table 11. The polarizability tensors are given for certain species of D±h point groups. an improper choice of the correlation table does not alter the predicted spectral activity. This is not the general rule, as the reader will find by experience (e.g., see [9]). When the results are compared by using both correlations in Table 11, a difference in the presence of the polarizability tensor is noted (see Table 12). Summarizing the differences in Table 12, we find that Blg species contain the polarizability tensor (axx — ayy), whereas species B2g possesses <xxy. Of course, polarized Raman studies on
4. Correlation of the Site Group to the Factor Group 29 this orientated crystal would detect this difference; however, the experimental results are extremely difficult to obtain for this phase of the crystal. This mistake will not occur if the proper choice, i.e., C2 ~> Cg, is made in the correlation tables; however, we felt it useful to include an example of an improper choice to acquaint the reader with this problem. (Chapter 2 and especially Table 14 contain a description of the correct selection of correlation tables.) Lattice Vibrations of Iodine Ions information : I, site CAv, Z = 2 (Table 4). IODINE CAv site symmetry species D^h factor containing correlafcioiV group ^ fy ty translation species C$ a^ = aAi + aE 2 \{TZ) Ax ____^ Alg 11 1 0 "" " -A2u(Tz) 11 10 4 2G*, J E =z Eg 2 10 1 ?«(rM) 2101 + A \ J? acoust — ^-Zu i -L'w Summary of the lattice vibration in the NH4I crystal: 7 + A2u + Eg + Eu) (Alg + A2u + Eg + £J - (^2w + £w)
30 Practical Methods for Selection Rules Rotations (Librations) of the NH| Ion in the Crystal The rotations of the NHj ion about the x9y, or z axis have the same character as the rotations (RX9 Ry, and Rz) contained in the character table of the D2d site group. Therefore the species for the rotations parallel to the x, y, or z axis will be easily identifiable. The correlation method is now applied to relate the rotations of the site group to the specific species of the factor group. The following slight modifications are necessary in treating these librations: where Ray is the degree of rotational freedom contributed by y species of the site group. Also, Rac = 2y R(lr B) rBb = |V£ (ii) Of course, we note that A0) and A1) are identical to B) and F), respectively, with only the superscript R added to indicate rotation. J Librations information: NEj-site D2d, ZB == 2 (see Table 4). D2d site symmetry species D±h factor with co"f*tto% group fyR Ry rotation 2~* 2 species C? a^ = aAz + aE 11 10 1110 2(RXJ E __ Eg 2 10 1 ^2 1 0 1 Eu
4. Correlation of the Site Group to the Factor Group 31 If the incorrect correlation tables C2 -> C2 given in Table 10 were used here to map D2d into DAh, the following irreducible representation would be obtained: rrCir°; = A2g + B2u + Eg + Eu. Comparing these two irreducible representations for the librations, we note the following difference: r^|~>C2 indicates a Hbration in species B2u, whereas F^"*0* does not contain species B2u but instead has species Blu. Therefore the representation differs in the presence (or absence) of species B2u and Blu. Neither species Blu nor B2u are infrared or Raman active; therefore in this specific case the selection rules are unaffected by the choice of correlation table. The proper choice of the correct correlation would be important in predicting the spectral activity of overtone, combinations, and difference tones for which the symmetry of this Hbration must be correctly known. Chapter 2 describes a method that relieves the uncertainty in making this selection by giving the correct correlation tables for each site at which the ambiguous case exists. The reader is referred to Durig's paper [6] for an excellent application of deuteration studies which distinguished between the lattice vibration and the Hbration in this crystal. Intramolecular Vibrations of NHj Ion The correlation method can be used again to place the different intramolecular vibrations of the NH^ group into the proper species of the site group or factor group. First, the number of intramolecular vibrations of the NHj ion can be obtained by using Td molecular symmetry of this particular ion. (Details of this method are described in Chapter 4, p. 79). The irreducible representation is F = Ax + E + 2F2. These molecular vibrations are then correlated to the D2d site species and the site species are integrated into the factor group in the following
32 Practical Methods for Selection Rules manner. Here, to avoid clutter, each species of Td molecular symmetry is dealt with separately. A new column, rvib, which is the degrees of vibration freedom of the single ion NHj, is introduced. For these molecular vibrations the following summation is used: vYih = 2y a-fiy = 3n -6 = l'CAi + lCE + 2CV2 - 9 (where Cy is the degeneracy of the species y of the molecular point group in this example Td). Also, fy=ZB- vYih, where ZB = number of NHj molecules in the Bravais cell; therefore, fy becomes the degree of vibrational freedom in the Bravais cell. This procedure is summarised on p. 33. information: NH4 ion Td molecular symmetry, D2d-site symmetry, and ZLft factor group symmetry. ZB = 2 (see Tables 1 and 4). The irreducible representation and spectral activity can be summarized in the following manner: Crystal Translations Intra- Spectral symmetry (lattice Acoustical Rotation molecular activity D4h vibrations) vibration (libration) vibration D^h Alg 1 2 R a\ A,., 1 1 1 1 1 2 1 2 1 2 2 2 R R R II II final check: Total vibration CN) =9+3+6 + 18= 36, where N = 12 for the NH4I crystal.
Molecular symmetry = * "vib 'vib correlation >» Site symmetry ™2d Co —>Co correlation ^h factor group species 2 4 12 E 1 1 1 1 1 1 2 2 1 1 1 1 1 1 1 1 2 2 2 2 £gj vib B2u) + (B2g + Alu) + 2(Eg + Eu) + 2(Blg + A2u) = 2Alg + \B2 2Blg + 2B2u + Alu + 2A2u + 2Eg + 2EU
CHAPTER TWO SITE SYMMETRY AND CORRELATION TABLES PART 1 SITE SYMMETRY The first example that had an ambiguous choice of site symmetry was the equivalent set of oxygen atoms in TiO2. Recalling from the x-ray information that four equivalent oxygen atoms are present in the Bravais cell, we could place this equivalent set on either a CafcD) or a C2uD) site. Actually the Wyckoff tables [8] on the published crystallographic data indicate the site position of each equivalent set of atoms in the following notation: Wyckoff's Tables for TiO2 Wyckoff Atom notation Site position Ti (a) 0, 0, 0; 0, J, | Oxygen (e) 0, 0, u; 0, 0, u; 0, J, u + J; 0, |, J - u 35
36 Site Symmetry and Correlation Tables We could consult the crystallographic tables [7] and identify the site from the x,y, z coordinates; however, a much simpler procedure can be followed. Appendix I presents the site symmetry in alphabetical order. Using TiO2 as an example. Appendix I gives space group 141, 2D2dB), 2C27iD), C2vD), 2C2(8), CxA6), for Dfh. Noting that DZd, C%ny and C2 appear twice, we can write the following alphabetical ordering from the data in this appendix: Wyckoff notation or Site in Alphabetical alphabetical ordering Atom Appendix I order of site position (site)a 9/~) @\ Pi (c)\ o Titiininm ^ 2d\ / 2d\) t«.iiiuxii (a) b c d e 2C2(8) C.(8) C,(8) f g h Oxygen (e) a Information from WyckofTs table and references cited therein. The alphabetical letter in parentheses following titanium in WyckofFs table indicates the site of the atom, i.e., (a) indicates that the titanium is on site D2d. For titanium this could have been determined by previous considerations; however, the site position of the four equivalent oxygen atoms appears to leave us the choice of either the C2^D) or C2vD) sites, for, as noted before, both sites will accommodate four equivalent atoms. Wyckoff's tables give the position of the oxygen atoms on an (e) site. Examination of the alphabetical tabulation of sites shows that the (e) site is C2v. Therefore there is no ambiguity in the choice
Site Symmetry and Correlation Tables 37 of site position for atoms, molecules, or ions if all the information given in crystallographic tables is properly used. Another example of the proper use of the crystallographic information is the a-Al2O3 crystal which is Rjc == D\dy Z — 2. By consulting Appendix I (p. 177) for D\d we find 2>8B), C3iB), C8D), C<F), C2F), ^A2). Obviously the four equivalent aluminum atoms can be accommodated only on the C3D) site. The six equivalent oxygen atoms, however, might be located in either the QF) or C2F) site. Wyckoff5s table gives the following information for a-Al2O3: Wyckoff Site Notation Aluminum: (c) Oxygen: (e) Therefore use of the tables in Appendix I (p. 177) with the sites arranged in alphabetical order proceeding from left to right implies the following tabulations: Site Alphabetical order Atom (site) D3B) a C3D) c Aluminum (c) QF) d C,F) e Oxygen (e) f These two examples illustrate the point that it is a simple matter to determine the site symmetry of an atom, molecule, or ion in a crystal lattice from information provided by x-ray experiments. Again note that all the sites are arranged in alphabetical order in Appendix I (p. 171). The table in Appendix I is similar to that provided by Adams [10], except for two major changes: (a) a reduction in the number of atoms found in the Bravais cell site from that given for the sites of the crystallographic cell, and
38 Site Symmetry and Correlation Tables (b) the arrangement of the site in alphabetical order to be consistent with Wyckoff's ordering and the crystallographic tables. PART 2 DERIVATION OF CORRELATION TABLES AND THEIR RELATION TO THE WYGKOFF SITE NOTATION 1. DERIVATION OF CORRELATION TABLE A selection of correlation tables appears in Appendix III (p. 201); however, we choose to show the derivation of several tables. By following these examples we can eliminate the problem of choosing the correct correlation table when two or more possibilities exist or, in some cases, when no direct correlation is given in the published tables. The first example is the simple correlation of the point group C3v to DZh. First, we write the point group C3v found in Appendix II (p. 184): A A2 E E 1 1 2 Operations 2C3(z) 1 1 -1 3av 1 -1 0 We note that CZv is a subgroup of DZh. This property was easily recognized, for we see that Dzn contains the same symmetry operators as CZv\ i.e., E, 2C3(z), 3^ plus additional operations &h, 2SZ, and 3C2. To obtain the species of C3v that correlate with those species of D3h we need only compare the
1. Derivation of Correlation Table 39 character of the operations common to both point groups Dzn and C3v, which in this case are E, 2C3(z), and 3cfv. To do this we simply write the partial character table of D3h, including only the operations common to both C3v and Dzn: Species of D3h point A[ A'[ A', A'i E' E" the group E 1 1 1 1 2 2 Operation 2C3(z) 1 1 1 1 -1 i —i -i i 0 0 - Species of the C3D point group A ] a2 Ax ) * Point group DZh: species A[ Point group C3v: species At Character of the operation 2C3(z) 3a* Therefore the correlation is to DvhA!x. Character of the operation E 2C3(z) 3av Point group D3h: species Ai Point group CZv: species A2 The correlation is C*VA<> to D*hA". -1 -1
40 Site Symmetry and Correlation Tables The other correlations found are summarized below: c3v A.\ A^ A2 Jx-y A'i A2 Ef E Ao A9. E" E The correlation between D2d and D±h is a bit more complicated, since D^h contains two different subgroups that are identical to D2d. It is best to illustrate this case with the specific example: first the point group o(D2d can be written as follows: Point group A A2 Bx B2 E E 1 1 1 1 2 2S,{z) 1 1 -1 -1 0 St EEE C2 1 1 1 1 —2 2C'Z 1 -1 1 -1 0 1 -1 -1 1 0 Now the operations of ZL7l, which are similar to ZJd, are two sets or subgroups: A) E, 2St(z), C2, 2G^ 2aa B) £,2.S4(z),C8,2C2,2er, These subgroups differ only in the presence of the C2 and tfd in subgroup 1 and the replacement of these operations with C2' and av in subgroup 2. Repeating the procedure already discussed, we can write the operations common to both point groups D±h and D2d.
Subgroup 1 ofiV Ag Au Ag Au Bi» B%g Biu Eg K Subgroup 2 of D,n Ag Au Ag Au Blu B2g B2u Eg Eu Hi ^*^4V 1 ] 1 __ 1 1 — 1 - 1 I 1 2 ( 2 ( E 2S4 ( 1 1 - 1 ] 1 - 1 - 1 1 - 1 2 ( z) Si = C2 [ 1 1 1 I 1 L 1 I 1 I 1 L 1 I 1 ) -2 ) -2 I 1 I 1 L 1 I 1 I 1 I 1 I 1 I 1 ) -2 2 0-2 2C'2 1 1 -1 -1 1 1 -1 -1 0 0 2CI 1 1 -1 -1 _1 -1 1 1 0 0 1 -1 -1 1 -1 1 1 -1 0 0 2av 1 -1 -1 1 1 I I 1 0 0 Species with same character in point group D2d A1 Bi A B2 B\ A B2 A E E Species with same character in point group D2d A A B2 B2 A B1 A1 E E 41
42 Site Symmetry and Correlation Tables TABLE 13 The Two Correlations Relating D±h to D2d AlU Bl Bl Jj-t „ Jj, /Jo "iu Ai A2 B2g B2 B± Eg E E Eu E E The correlations that relate Dih to D2d are given in Table 13. Therefore to choose the correct correlation table we must consider the symmetry elements in the site group and which of these symmetry elements coincide within the factor group. This is exactly the problem we face in selecting the proper correlation tables in the TiO2 and NH^ ion examples already discussed. Here we must decide whether the C2 element of the site D2d coincides with the C2 element of the factor group. Also, in this correlation the ad plane of the site group must coincide with the <jd plane of the factor group. If this coincidence occurs, we can choose the correlation tables marked C2 -^-C'z above or, as in Appendix III (p. 206), the column marked C2. This, however, is not the case for TiO2 and NH^ ions, for we find that the C2 element of the site coincides with the C2 operation of the factor group and that the av plane of the site is the same symmetry element as the ad plane of the factor group; then we must correctly choose the correlation tables headed by C% -> C2 as given above. [See also Appendix III (p. 206), D±h to D2d column headed by C2.]
2. Relationship to Wyckoff Site Notation 43 2. RELATIONSHIP OF CORRELATION TABLES TO WYCKOFF SITE NOTATION There is a need for a simpler method of determining the correct correlation tables. All this information is contained in the crystallographic tables, Reference 7, but is not in an accessible form. Therefore we prepared Table 14, which lists the Wyckoff sites of interest for some space groups and identifies the correct correlation tables. The correlation table identification refers to the tables given in Appendix III. Crystal TiO25 Space Group D^-141 1. The oxygen is on Wyckoff site (e). Referring to Table 14-Z)^, we see that site (e) is in column C2, <rv. Here we find that the relationship between ZLft and C2v given in Appendix III allows four possible choices: Dih Alg T C2, av civ Al A, C2, ad C2v Ai • C2 c2v • a c2v Ax However, Table 14-Z>4^ gives the proper choice as the column headed by C2, av. 2. Titanium atom is on the Wyckoff site (a). Table 14-D^ for space group 141-D^ has this site (a) in column C2\ Referring to Appendix III (p. 206), we use the correlation table for D±h to D2d headed by C2. NHj Ion on Wyckoff Site (a) In Table 14-D^ for the space group 129-D^ the (a) site is in column C2. In Appendix III the correlation relating to D^n to D2d uses the column headed by C2 for this site to factor group relationship.
TABLE 14 Identification of the Proper Correlation Table to be used in Relating the Site Symmetry Given by the Wyckoff Description0 Site correlation Space group number ^2{z) QO) C%(x) a(xy) o(zx) <?(yz) 16 17 18 20 21 22 23 24 25 26 28 31 35 36 38 D\ Dl Dl D\ D\ D\ D\ D\ c\v civ dv Qll c12 cl4 q, r, s, t a,b ij,k g> A i,j c m, n, o, p c,d b g,h f> * ft* b a,b a e,f e,j e,f a *>f g, A a, b c a e a d, e
s s 45
TABLE 14 (continued) Space group number 62 63 64 65 66 67 68 69 70 71 72 73 74 7I6 n17 D18 n19 JJ2h ^2h rJ2 Dll ^2h D25 n26 rJ7 D28 Space group number D{ 89 90 D\ D\ C2(z e,f, k, I, m c d e f i g>l g> h e, i,j g i,j c> d, h, i e e i d e,fj c e hj h f d, h, h f g,h g d c> d,g \ m, n, o a, a, g> g c> e c, e <?, f c a, cl j9k C2(x) b,e b,d h d, K i g> l f a{xy) g P> q i 0 n j c2 °* o(zx) c 0 n n m i <** a{yz) f f n m m I h
s s- q Q q q q q 47
TABLE 14 (continued) Space group number C'l C2 ad D\n 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 D\d Did Z)9 7I0 D11 D\\ D\h D\h D\h D\h 7~\5 n6 ^4/1 D]h Din Din D10 7I1 D12 TI3 e, e, f, h c h g c, e f, f, h a. f h g e f k g f,g g>h e,h f,g d e,f, m, n, o c, d, k, I a> b, c, d9j, ky /, m b, d9 e9 I, m a, b, h, i a, b9 c9 i,j hk h c, d, g, h d,g a, b, d, e a, c9 i,j g,'h f e,f, K I h f g,h g P> q m h q n i t P r n k j 0 71 d,g
TABLE 14 (continued) Site correlation 136 137 138 139 140 141 142 /) Dll Dlt D17 D18 ZI9 D%2 cy h f d b: c> e tj dj a> b>f> g a, b>f a, c, d, g, h dj> K k d9 e, h, i ^ b9g b.f c9d I k I m I Space group number C9 Space group number Space group number Jh uv TQ 111 Dl i j,k c9d9l9m 178 Dl a b 179 D\ a b 180 Di ej g9h ij 181 Dl ej gyh ij 182 Dl a,g b,c,d,h CL 183 Cl b,e 185 186 a, c a, b, c y*h 187 188 189 190 m n k h
TABLE 14 (continued) Site correlation Space group number Ci 191 192 193 194 Dlh gy i Din E>th j. J a a >k ,g c, k b9 d9f9 i b, c9 d9 h p, q h,on I I k j K ej Space group number c, Ol 207 208 209 210 211 212 213 214 O1 O2 O3 O4 O5 O6 O7 O8 h h,i,j i f g i i,j k, I g, h g h, i d d e,f d c,d
ol 221 222 223 224 225 226 227 228 229 230 ol ol ol ol ol ol ol ol ol ol° g d f f TABLE 14 (continued) Site correlation Space group number C2 3C2 C2, 2C'Z C2, crA C2, ah C2, <rd crfc crd iyj h k9 I m h b c, d>j f>g>h k f hj g k d h,i g j k c, h e i h f g g L d, h v j k a a, b, c, . . . , to the space group. Correlation tables are listed in Appendix III.
CHAPTER THREE THE BHAGAVANTAM AND VENKATARAYUDU METHOD Since SrTiO3 has already been treated by the correlation method, it would be worth while to repeat this calculation, using the method proposed by Bhagavantam and Venkatarayudu [3], to determine (a) whether both methods give the same result and (b) to demonstrate the simplicity of the correlation method. Only a simple outline of the Bhagavantam and Venkatarayudu method is given here. I. The irreducible representation for this crystal can be obtained as follows: By definition coR = the number of atoms left invariant under operation R %v = the character of the operation i?, obtained in the following manner +2 cosS) 53
54 Bhagavantam and Venkatarayudu Method The angle 0 is defined as follows: (a) where E is a proper rotation, 0=0°; 360 (b) (+) used for proper rotations, C^ d = —^- ; 360 (c) (—) used for improper rotations, Svi 6 = —- ; (d) ah is an improper rotation with 0=0°; (e) i is an improper rotation with d = 180°. Next, each operation is considered in obtaining ooR and %v. Crystallographic information for SrTiO3, a perovskite, is O\-PmZm. First the crystal structure with atoms in the position of the unit cell shown in Figure 1 must be considered. This same unit cell is used throughout this discussion. In the unit cell of this crystal structure (see Figure 1) • = titanium atom O = oxygen atom Sr = strontium Figure 1. The crystallographic unit cell of SrTiO3.
Bhagavantam and Venkatarayudu Method 55 Note, (a) Each Ti is shared by 8 Sr; (b) there are 12 oxy around 1 Sr. To check: Atom Ti-8 per cell, each contributing \ to the unit cell: 8 x i = 1 Ti oxy-12 atoms, each oxy contributed £ to unit cell; 12 x \ = 3 O Sr-1 atom in middle of cell 1 Sr atom per unit cell = 1 Sr Total coR = SrTiO3 for Z = 1. A. E Operation: Character and number of atoms invariant under E operations can be found as follows: All the atoms remained unchanged: .*. coR — 5 (i.e., 1 Sr + 1 Ti + 3 oxy), ^ = 5( + l + 2 cos 0°) = 5 • 3 = 15. B. C3 Operation: The illustration that follows shows some of the C3 elements of symmetry in the unit cell. The list that accompanies it is a tabulation of the number of atoms left invariant under all the Cz operations and the irreducible representation %v. Comment There are 7C3's passing through this unit (Figure la); all are parallel to one another (note that this is not the 8C3 operation
Figure la Figure Xb 56
Figure lc Figure Id 57
58 Bhagavantam and Venkatarayudu Method Figure le that appears in the character table, but only one of these eight operations). Operation Number of atoms invariant, wR XC3 1 Sr + 2 • | Ti iTi iTi iTi Total atoms 1 Sr + 1 Ti However, for all C3 operations 1+2 cos 6 (where d = 120) = 0, where d = 120°. .'. (oB{\ + 2 cos d) =0
Bhagavantam and Venkatarayudu Method 59 C. Since this example illustrates the procedure followed on each symmetry operation, only the essentials are presented in the discussion for obtaining a>R and %v for each operation. (See Figure \b.) Operation Number of atoms invariant, coR D. 2C* o2 6c2 Total atoms Operation 1Q 2c4 3C4 4c4 = 1 2 2 2 1 Sr •* • i Sr + ■ + i I 2 • t * 2 • 2-ioxy oxy oxy -|Ti Ti Ti Ti iTi 1 oxy + 1 Ti 1 Ti Ti Ti Sr + + + (see Figure \c) ioxy Joxy ioxy 2 • i Ti + | oxy ^ ^r — lor + 1 li + lO—o Operation co^ (see Figure Id) xCa 1 Sr 2^2 2 • i Ti + i oxy 3Ca 2 • i oxy 4^ 2 ■ i Ti + i oxy 5Cs 2 • i oxy 6Cs 2 • i Ti + i oxy 7Cs 2 • i oxy 8C2 2 • i Ti + i oxy 9Cs 2 • i oxy .-. 2 ^i? = Sr + Ti +3 oxy =5
60 Bhagavantam and Venkatarayudu Method F. z-operation Note. There is a center of symmetry at every atom in the unit; therefore all the atoms remain invariant under one of the many z-inversion operations, i.e., 1 Sr + 1 Ti + 3 oxy, for £ coR = 5. G. Comment The S& operation yields the same result as the C4 operation, even though there is the additional reflection. If we note that Intersection — of reflection plane Figure 1/ there are three reflection planes in the unit cell and all the atoms lie on one of these reflection planes and the £4 axis, we find ooR = 3. (See Figure 1*)
H. Bhagavantam and Venkatarayudu Method 61 Operation a>R (see Figure If) 1 Sr + 2 • i Ti iTi iTi Figure Ig I. All atoms are invariant under ah\ (See Figure \g) .". 2 mr = 5 J. Operation coR (see Figure 1ad 2 • i Ti + J oxy 2ad 4 • i Ti + 2 ■ I oxy + Sr 3^ 2-iTi + ioxy
62 Bhagavantam and Venkatarayudu Method -O Figure 1/z The results can be summarized in tabular form: Class (Oh factor group) E 8C3 6C2 6 C4 3C2 i 6^4 8 Se 3 ah 6 ^ 5 2 3 3 5 5 3 2 5 3 15 0 -3 3 -5 -15 3 0 5 3 II. Calculation of the number of modes in each of the species. n(y) = number of modes in each species, y g = order of the group, g = ^igi gi = number of elements in each class Xiy) = the character for the class i and irreducible representation Ty
Bhagavantam and Venkatarayudu Method 63 = character of the irreducible representation, derived and tabulated above Example of its use: 1. A± Species ~ 2 xflg X$i Si E = i = 15 = 1 8C3 1 0 8 6C2 1 — 3 6 6C4 1 3 6 1 —5 3 i 1 -15 1 eSi 1 —3 6 8S6 1 0 8 1 5 3 6ad 1 3 6 IXi'Jn'Si = 15 + 0 _ 18 + 18 _ 15 _ 15 _ 18 + 0 8 = 48 + 15 + 18 = 0 Therefore there are no lattice vibrations in Alg species. 2. Flu species X?1" Xp Si E o - 15 = 1 8C3 0 0 8 6C2 -1 -3 6 1 3 6 -1 -5 3 i -3 -15 1 -1 — 3 6 8*6 1 0 8 3*, 1 5 3 1 3 6 gi = 45 + 0 + 18 + 18 + 15 + 45 + 18 + 0 £=48 +15 + 18=4 Therefore there are 4Flw irreducible representations. 3. F2u species Xf2u Xv Si E = 3 - 15 = 1 8C3 0 0 8 6C2 1 — 3 6 6C4 _1 3 6 -1 -5 3 i -3 -15 1 6St 1 -3 6 8^6 0 0 8 3cr, 1 5 3 6od -1 3 6 iavt Si =45+0-18-18 + 15+45-18+0 = 48 + 15 - 18 = 1
64 Bhagavantain and Venkatarayudu Method Therefore there is lFZu irreducible representation. 4. All the other species of 0h give zero irreducible representations. 5. Summary: poryst = 4Fiw +i?2w pcryst = pcryst _ pacoust _ ^ + ^ _ ^ This checks the result in Example 2, p. 21. It is now easy to compare the two methods to establish that the correlation method takes only minutes, whereas this procedure involves much more time.
CHAPTER FOUR MOLECULAR SELECTION RULES The molecular selection rules are easily obtained by the correlation method. Tables which give the number of normal vibrations in each species for several point groups have already been published (see Herzberg [12]). We choose to use the correlation method here to demonstrate its general applicability to molecules and to provide a completed set of tables (see Table 24) for all physically possible molecules. 1. APPLICATION OF CORRELATION METHOD Slight modifications are necessary in the correlation method applied to crystals before this procedure can be applied to molecules. The following rules give these modifications for obtaining the irreducible representative for all normal vibrations (rmolvib). 65
66 Molecular Selection Rules 1. The molecular symmetry must be known or determined. Several texts describe these point group classifications for molecules (for examples see [12]). 2. The site symmetry for all equivalent sets* of atoms in the molecule must be known or determined. First, if unknown, the symmetry elements contained in or passing through the atom must be found. Second, these elements of symmetry form a complete set of operations belonging to a specific point group—the site symmetry. Z is the number of atoms in an equivalent set. 3. Application of the correlation method as already described. 4. The irreducible representation for the molecule (rmo1) obtained includes both the genuine normal vibrations (rmo1 Vlb) and nongenuine motions that take the form of pure rotation and translations of the molecule. These nongenuine motions can easily be removed by subtraction as follows: ■pmol vib ipm.ol -ptrans -prot I 5. Identification of the spectral activity of each species of the molecular point group. (See Appendix II, p. 181.) 2- EXAMPLES The following examples provide some applications of the correlation method 'for determining the number of normal vibrations of a molecule. Benzene The symmetry elements present in benzene are shown in Figure 2. This figure also illustrates those symmetry operations * Equivalent atoms: definition. A set of identical atoms that can be transferred into one another by the symmetry operations present in the molecule (see [12], especially p. 131).
2. Examples 67 CgjCr, Symmetry Elements: o;(yz),crh(xy) V Fig. 2a Figure 2. Benzene symmetry. The z axis is perpendicular to the plane of the molecule ah and passes through the inversion point i found at the center of the hexagon. The z axis contains the elements of symmetry C6, C3, C2, S^ and Ss not shown in this figure. The molecular point group is D^. The isolated portion (Figure 2a) at the right, considers only one carbon and one hydrogen atom. This illustrates the presence of only those symmetry elements E, C2, Gv(yz), thus the site symmetry of the carbon and hydrogen is C2-y present in each hydrogen and carbon atom. The symmetry elements present in each atom immediately allow us to identify \ the site symmetry as C2v; i.e., the operations E, Ca, &vy ah passing through the hydrogen site describe the point group CZv.* The correlation of the site symmetry CZv for the hydrogen atom to the molecular symmetry D6h is given in Table 15. Since there are six equivalent hydrogen atoms per molecule, Z = 6. The irreducible representation rH, derived in Table 15 for the hydrogen atoms, is exactly the same as the irreducible representation rc for the carbon atoms (this is always true if the site symmetry and number of equivalent atoms Z are the same for two nonequivalent atoms). The total irreducible representation for benzene is the sum * Note, for example, that the operations, C6, SQ9 i, do not pass through the hydrogen atoms; therefore they are not included in the description of the site symmetry of the hydrogen atom.
68 Molecular Selection Rules TABLE 15 Benzene. The Correlation Between Site and Molecular Symmetry Species for the Hydrogen Atom (Z = 6) Site Molecular f symmetry c°7elaA!,on> symmetry 6 1 6 1 6 1 1 = 1 1 = 0 = 1 = 1 = 2 = 1 0 = 1 = 1 = 1 2 = 1 1 = Ag + T~ Bla Note. The site symmetry and Z of carbon are exactly the same as hydrogen; therefore, FH = Fc. of the irreducible representation for each equivalent set of atoms given in Table 15; i.e., pmol pH | pC The irreducible representation for the molecular vibration pmoi vib can easjjy J3G founc] by subtracting the irreducible representation of the rotations Frot and the translation Ftrans from the total representation: pmol vib __ pmol prot p -i trans
2. Examples 69 This procedure is outlined in tabular form: 0£, species coefficients (see Table 15) rH= 1 10 1 12 0 111 21 rc = i 101 120 ill 21 Adding pnol = 2 202 240 222 42 Subtracting __prot _ i „ i ptrans y j pnol vib:=2 102 140 122 32 or pmol vib 9^(R) 4_ ^(O) _i_ 9n@) i /rdt) _j_ 4.f(R) _i_ j(IR) i or@) 1 — **^\g T" ^2g ' ^a2g * ^\g ' ^^Zg « ^2W ' 4D1m Repeating the use of superscripts in Table 9, IR is infrared, R is Raman, and @) is no spectral activity. This method predicts four infrared fundamentals, A%u + 3Elu, seven Raman fundamentals, 2Alg + Elg + 4EZgy and no coincidences in the infrared and Raman spectra. 1,355-Trichlor obenzene Figure 3 shows the symmetry elements present in the 1,3,5- trichlorobenzene and the various site symmetries. The following summary can be made of the site symmetries. Ring atom position Site symmetry Atom in equivalent set Carbon A, 35 5) C2v, Z=3 Carbon B, 4, 6) C2v, Z = 3 Hydrogen B, 4, 6) C2v, Z - 3 Chlorine A, 3, 5) C2v, Z = 3
Symmetry Elements: E,C2, ^z),crh(xy) Fig. 3a J ^o;(xy) Symmetry Elements: E,C2, crvfo-h(xy) \^ Fig, 3b ^/ Figure 3. 1,3,5-Trichlorobenzene symmetry. The z axis is perpendicular to the plane of the molecule ah(xy) and passes through the center of the hexagon formed by the carbon atoms. Not shown here are the symmetry operations C3 and 6*3 contained in the z axis. The molecular point group is Dzh. The isolated portion (Figure 3a) shown at the upper right illustrates the presence of symmetry elements E, C2, <yv{yz)i 0h(xy) for the chlorine (Z = 3) and carbon (Z = 3) atoms in positions 1, 3, and 5 of the ring. The lower right-hand portion (Figure 3&) illustrates the presence of symmetry elements E, C2, Gv, Oj^xy) for the carbon (Z = 3) and hydrogen (Z = 3) atoms in positions 2, 4, and 6 of the benzene ring. Thus the site symmetry of all these atoms is C2v. 70
2. Examples 71 From the correlation in Table 16a the irreducible representation for the molecular vibration (rmo1 Vlb) can be constructed as follows: Atom's position a^ species coefficients on benzene ring A' A' Pf A" A" F" rcl = 1 i 20 i i i, 3,5 r° = i i 20 i i i, 3,5 Tc - 1 1 2 0 1 1 2,4,6 rH = 1 1 2 0 1 1 2,4,6 ^* peq sets _ pmol = 4 4 80 4 4a prot __ 2 j ptrans __ j j pmol vib __- 4 3 7 0 3 3 j-'mol vib a Ar _i Q Af i_ *l fPf _i % A" _|_ 3Wff where there are 10 infrared fundamentals, IE' + 3 A I, and 14 Raman fundamentals, 4?A[ + IE1 + 3E". a The same result would have been obtained if the total number of equivalent atoms with site group C2v had been used. Table 16b illustrates this by using Ztotal = ZcF) + ZHC) + ZC1C) - 12. Hence a considerable savings in time would be realized if the total number of equivalent atoms with specific site symmetries were used in the correlation procedure.
TABLE 16a 1,3,5-Trichlorobenzene. The Correlation for the Site Group C2v to the Molecular Symmetry Dzh for the Chlorine Atom Z-3 r 3 3 3 ty 1 1 1 Site symmetry C2v A A, Bit - B2 - - rci Correlation^ = Ai + A2 - Molecular symmetry A'{ \-2E' + Al- i ■ *• i 2 = 1 0 = 1 = + E" ay 1 1 \~aB2 1 1 Note. TCI = rc (for carbon in 1, 3, 5 position) — Fc (for carbon in 2, 4, 6 position) = rH (for hydrogen in 2, 4, 6 position) TABLE 16b 1,3,5-Trichlorobenzene. The Correlation Between the Site Group and Molecular Symmetry Species for All Equivalent Sites of Atoms with C2v Site Symmetrya r 1° 12 12 ty I 1 1 Site symmetry c2v A]^ Bi - ^ B2~^ r = Correlation^ AA[ + 4A'2 - Molecular symmetry A'l --E' f BE' + 4^S /i. 4 8 0 4 4 + aA,- 4 = 4 — = 4E" ay 4 4 + ^t 4 4 a Here ZC1 = 3, Zc = 6, ZH = 3 for a total Z of 12 atoms with C2v site symmetry. 72
2. Examples 73 1,4-Dichlorobenzene The symmetry operations found in 1,4-dichlorobenzene are shown in Figure 4. The site symmetries identified in this figure are summarized below. Atom on site Position on Atom in benzene ring Site symmetry equivalent set Chlorine Carbon Carbon Hydrogen 1,4 1,4 2, 3, 5, 6 2, 3, 5, 6 C2v, c2v, cs, cs, Z = 2 Z = 2 Z = 4 Z = 4 The irreducible representations given in Tables 17 and 18 are summarized below. pc,ci = pC,H __ prot ptrans Ag 2 4 Blg 0 2 ~1 B2g 2 2 -1 BZg 2 4 -1 K 0 2 Bin 2 4 — 1 B2u 2 4 -1 2 2 ~1 Position on ring 1,4 2, 3, 5 and 6 pmoi vib=6 or pmol vib 52 Thus there are 15 Raman fundamentals, 6Ag + Blg + 3BZg + 5^3^, and 13 infrared fundamentals, 5Blu + 5B2u + 3B3u, with no expected coincidences.
I C2(z),CTxz Symmetry Elements: E,C2(z), Fig. 4a Symmetry Elements: E,c Fig.4b Figure 4. 1,4-Dichlorobenzene symmetry. The x axis is perpendicular to the plane of the molecule o^yz) and passes through the inversion point i found at the center of the molecule. Not shown is the presence of the C2{x) operation coincident with the x axis. The molecular point group is D2h{V^). The isolated portion (Figure 4a) at the upper right illustrates the presence of the symmetry operations E, C2, <y{zy), a(xz) contained in the chlorine (Z = 2) and carbon (Z = 2) atoms found in positions 1 and 4 of the benzene ring. The site symmetries of these atoms must be C2v. The isolated portion (Figure 4b) at the lower left identifies the symmetry operations E and cs{zy) contained in the carbon (Z = 4) and hydrogen (Z = 4) atoms in positions 2, 3, 5, and 6 of the ring. Thus the site symmetry of these atoms is C-. 74
TABLE 17 1,4-Dichlorobenzene. The Correlation Between the C2v Site and the Molecular Species D 2h r 4 0 4 4 1 0 1 1 rc, Site symmetry A A ^ C1 = 2i4, + Correlation, \ -\- - -\r - 2B2g + 2B3g Molecular symmetry A A9 Blg ' ~B2g - - ~BZg \ K -:b2u ^3» ai 2 = 0 = 2 = 2 = 0 = 2 2 - 2 - + 25lu + 2B2a : 2 : 2 ay V«Bi- 2 2 f flJ?a 2 2 a The number of equivalent atoms Z — 4 includes the equivalent sets of carbon atoms (Z — 2) and chlorine atoms (Z = 2) in the 1 and 4 positions TABLE 18 1,4-Dichlorobenzene. The Correlation Between the Site and Molecular Species for All the Carbon and Hydrogen Atoms in the 2, 3, 5, and 6 Positions (Z = 8) f Site nm< symmetry ^g«o£^ Molecular symmetry D9 ar = '2h 16 A! 2 2 = 4 = 4 = 4 75
76 Molecular Selection Rules Chlorobenzene Figure 5 illustrates the symmetry operations present in chlorobenzene. The site symmetries shown in this figure are summarized: Site atom Chlorine Carbon Carbon Hydrogen Carbon Hydrogen Position on ring 2, 2, 1 1 4 4 3,5, 3,5, 6 6 Site symmetry, c2v, c2v, c2v, cf> cv z Z= 1 Z = 1 Z= 1 Z= 1 Z = 4 Z = 4 Table 19 gives the correlation for the four nonequivalent atoms on CZv site. The correlation for the remainder of the atoms on site Cs is given in Table 19. TABLE 19 Chlorobenzene. The Correlation Between the Site and Molecular Species of the Chlorine, Hydrogen, and Two Carbons Atoms (Z = 4) r 4 4 4 ty 1 1 1 Site symmetry pCl,C,H _ Correlation __ _ Molecular symmetry c^ A + 4B2 4 4 4
Symmetry Elements: E,C2(z), V F\g.5a y 6 * Symmetry Elements: E, Fig. 5 b a. *y T -Z Symmetry Elements:E,C2(z), V Fig. 5c J Figure 5. Chlorobenzene symmetry. The x axis is perpendicular to the plane of the molecule a{zy) and passes through the center of the hexagon formed by the carbon atoms. The molecular symmetry is C2v. The isolated portion at the upper right (Figure 5a) illustrates the symmetry elements E, C2(z), a{xz), cr{zy) contained in the chlorine (Z = 1) and carbon (Z = 1) atoms in position 1 of the benzene ring; These atoms possess site symmetry C2v. The isolated portion at center right (Figure 5b) identifies the presence of the symmetry operations E, G(zy) in the carbon (Z = 4) and hydrogen (Z = 4) atoms in positions 2, 3, 5, and 6 of the benzene ring. The site symmetry for these atoms is Cs. The isolated portion at the lower left (Figure 5c) identifies the symmetry operations E, C2(z), o(xz), o{zy) present in the carbon (Z = 1) and hydrogen (Z = 1) atoms in position 4 of the benzene ring. The site symmetry of these atoms is C2v- 77
78 Molecular Selection Rules Chlorobenzene. The Correlation for the Carbon and Hydrogen Atoms in 25 3, 5, and 6 Position (Z = Z° + ZH = 8) f Site symmetry Correlation > o(xz)~>a{xz) Molecular symmetry aA' 16 2 8 1 8=8 0 4-0 4 8-8 0 4=0 4 4B2 The irreducible representation obtained in Table 19 is summarized below. pC,Cl,H = pC,H __ prot ptrans pmol vib C 4 8 -1 11 &£, species 0 4 — 1 3 coefficient 4 8 -1 I __ 10 4 4 -1 -1 6 Result from Table 19 Table 19 Therefore the irreducible representation of the normal vibration is mol vib There are 30 Raman fundamentals, 11^ + 3^4a + 6525 and 27 infrared fundamentals, IIAX + IOB1 + 6BZ.
2. Examples 79 Ammonium Ion, NHj The ammonium ion has Td symmetry. Again, the site symmetry must be determined for each equivalent set of atoms in the molecule. In the preceding four examples the figure of the molecule was constructed where the symmetry elements were identified, which, of course, leads to a description of the site symmetry for each set of equivalent atoms. There is still another means of determining the site symmetry. First, the equivalent sets of atoms are identified. This describes the number of equivalent atoms (Z) in each set. For NH+ with Td symmetry there are four hydrogen atoms in one equivalent set (Z = 4) and one nitrogen atom in the second equivalent set (Z = 1). Next, in Appendix I (p. 179), the space group T\ lists the site symmetries and the number of equivalent atoms that can be accommodated by each site for the molecular symmetry Td.* This information is tabulated as follows: 7^: 2Td{\), 2D2dC), C,,D), 2Ca,F), C,A2), C.A2), CiB4). Since only the 7^A) site will accommodate one atom, the nitrogen atom must be on this site. There are four equivalent hydrogen atoms which must be on a CZv site. We prefer this simpler, more rapid means of determining the site symmetries of equivalent atoms in a molecule. All preceding examples of benzenes, as well as NH^ ion, are described in Table 20 by this method. The results are identical to those already obtained for examples 1 through 5 which consider the symmetry elements present in equivalent sets of atoms. Application of the correlation method is given in Tables 21 and 22. The irreducible representation for the normal vibrations can be constructed as shown on page 83. General Molecule The foregoing treatment is applicable to any molecule as the following example illustrates. First, the molecule of concern is * The space group to the superscript 1 always describes the site symmetry present in the molecular group; for example, molecular symmetry Td is described by Tl D6h by D\h, D3h by D\n, D2h by D\h, C2v by C\v, and so on.
TABLE 20 The Site Symmetry for the Equivalent Sets of Atoms in Various Molecules Site symmetry Molecular Equivalent (from Equivalent atom Molecule symmetry space group Appendix I) (Z = number of equivalent atoms)a 1. Benzene D6h 191 P^/mmm = ^h 2ZNft(l) 2DWB) 2^C) 2. 1,3,5-Trichloro- benzene D* 4C,A2) 3C5F) Carbon (Z = 6); hydrogen (Z = 6) Chlorine atom (Z = 3) in positions 1, 3, and 5 Carbon atom (Z = 3) in positions 1, 3, and 5 Hydrogen atom (Z = 3) in positions 2, 4, and 6 Carbon atom (Z = 3) in positions 2, 4, and 6
3. 1,4-Dichloro- benzene D9 6CSD) 4. Chlorobenzene p mm2 = CiD) Chlorine and carbon atoms (Z = 2) positions 1 and 4 Carbon and hydrogen atoms (Z = 4) positions 2, 3, 5, and 6 Chlorine and carbon atom (Z = 1) position 1 Carbon and hydrogen atom (Z = 1) position 4 ["Carbon and hydrogen atoms (Z = 2) positions 2 and 6 | Carbon and hydrogen atoms (Z = 2) positions 3 and 5
TABLE 20 (continued) Molecule Molecular symmetry Equivalent space group Site symmetry (from Appendix I) (Z = Equivalent atom number of equivalent atoms)a 5. NHt p_ 7 43w ~ L d 2CLF) Nitrogen atom (Z = 1) Hydrogen atom (Z = 4) a The site symmetry for each set of equivalent atoms is described in the column immediately to the left of the atom. Note the number of equivalent atoms (Z) is always equal to the number in the parentheses of the site symmetry; for example, in benzene there are six equivalent carbon atoms; hence Z = 6. Therefore the site must be C2vF) for this is the only site that will accommodate the six equivalent atoms.
2. Examples 83 rH rN prot ■ptrans A = l = 0 = A, 0 0 species , E l 0 coefficients 1 0 -1 2 1 I Result from (Table 21) (Table 22) pmol vib = for the NHj ion T = A[ TABLE 21 Ammonium Ion, NH^. The Correlation for the Hydrogen Atom with Site Symmetry C3v) Z = 4 Site Molecular symmetry Correlation^ symmetry J l ^3v l d 1=1+0 0=0+0 0 ^ 2 E -I-I— ^^^--^ 1 = 0 + 1 2=1+1 E
84 Molecular Selection Rules TABLE 22 Nitrogen Atom. The Correlation for the Nitrogen Atom with Site Symmetry Td9 Z = 1 Molecular Site symmetry Correlation^ symmetry f ? Td Td a, AL Ax 0 A2 A2 0 E E 0 Fx F± 0 F2 1 classifiable as C2v molecular symmetry. Appendix I gives all possible sites in this molecule, summarized below. C2v molecular symmetry Designation of Equivalent equivalent sets of Sitea atoms on site atoms on siteb 1 Mo 2 Mxz or Myz 4 Mi a Space group 25 - Pmm2; C\v: 4C2v(l); 4QB); ^D) (from Appendix I). b Mx equals the number of equivalent sets of atoms not on any element of symmetry but possesses the symmetry element E, i.e., the identifying operation; Mxz, Myz are the numbers of equivalent sets of atoms lying on the xz and yz plane, respectively; Mo is the number of atoms lying on all symmetry elements.
TABLE 23 Correlation of all the Sites to the C2v Molecular Symmetry a. C2v sites; MQ is the number of equivalent sets of atoms on all elements of symmetry Site symmetry Correlation^ Molecular symmetry P MQ Mo B* b. Cs site using axz correlation table; Mxz is the number of equivalent sets of atoms on the xz plane r Site symmetry Molecular symmetry aA» A" =■ - I _ _ _. ^^ B ~~~ — — —. D 2MXZ = 2MXZ + 0 = 0 +MXZ 0 Mxz= 0 +MXZ 2MXZ = 2M c. Cs site using ayz correlation table; Myz is the number of equivalent sets of atoms on the yz plane P Site symmetry Molecular symmetry aA' + aA" ±Myz 2 2Myz = 2Myz + 0 Myz = 0 + Myz Myz= 0 +Myz 2Myz = 2Myz + 0 d. General sites; M is the number of equivalent sets of atoms on no elements of symmetry Site symmetry Molecular symmetry 12M 3MX 85
86 Molecular Selection Rules Table 23 lists the correlation of all these sites to the molecular point group C%v. In site Cs there are two possible correlations. Here the correlation axz is used when the xz plane passes through the sets of atoms; the equivalent atoms are designated MXz. Similarly, Myz is used to designate the equivalent set of atoms which lies on theyz plane. The resulting irreducible representations presented in Table 23 can be summarized as follows: 0£, coefficient of species Irreducible Site representation A± A2 B± B2 Results from C2v TM* Mo 0 Mo Mo Table 23a Cs(axz) T^xz %MXZ Mxz 2MXZ Mxz Table 23b cslavz) YMv* 2Myz Myz Myz 2Myz Table 23c Cx TM 3M± 2>MX 3M1 ZMX Table 23d -rrot -1 -1 -1 C2v character table _rtrans __ j _{ _j C2v character table This result is identical to that given by Herzberg [12]. By a similar procedure the irreducible representation for the normal modes of vibration can be calculated for all molecular point groups. Table 24 presents the vibrational contribution of each set of equivalent atoms Mi to the different normal vibrations of each species of the point group. The nongenuine vibrations, i.e., the rotations and translations, are substracted from the appropriate species and the spectral activity of each species is identified. TABLE 24 Number of Normal Vibrations and Selection Rules for Molecules Tables for the vibrational contribution of the different sets of equivalent atoms to the normal vibrations in each species of the point groups are given here: Mo is the number of equivalent sets of atoms on all elements of symmetry present in the point group; Mi is the number of equivalent sets of atoms on a site. The site identified at the top of each column is described for each M with
2. Examples 87 an appropriate subscript i; N is the number of atoms in the molecule, ion, or complex. This format is used in all the tables that follow. Point Group (space group, if any) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations Spectral8- activity Point group Site^(rc) Site?-(m), etc. Species Mi Mjy etc. —6 nonlinear R = Raman molecules activity — 5 linear IR = infrared molecules activity N = nMi + mMj + • • •, the number of atoms in the molecule, where Mt is the number of equivalent sets of atoms on site i and each equivalent set contains n atoms; Mj is the number of equivalent sets of atoms on site,/ and each equivalent set contains m atoms. a The selection rules for three- and four-photon Raman interactions are not present here; however, a paper by J. H. Christie and D. J. Lockwood, J. Ckem. Phys. 54, 1141 A971) gives some of these selection rules. C1 (Space Group 1 — PI) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity A N = Mx Cs (Space Group 6 -Pm)=C -6 IR, R Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity A' A" N 2M0 + SM1 = M0+2M1 -3 IR, R -3 IR, R
Q (Space Group 2 — C\) == Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity 3M0 Mo + 2M1 R IR A B N C2 (Space Group 3 — P2) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity 2M0 + 3M1 Mo -2 IR, R -4 IR, R C2h (Space Group 10 - P2jm) Q N 88 Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations C2h(\) C2B) C,B) Spectral activity M2 2M2 Mo + -M2 2M0 + 2M2 2M2 R R IR IR
C2v (Space Group 25 — Pmm2) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity C2V{\) zx plane yz plane CxD) 2MZ Myz 2My -1 1 o -2 IR, R R IR, R IR, R N = MQ ZJ (Space Group 16 - P222) s F Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations Spectral activity C2B) —— . ii 2JA) -s: axis y axis # axis A N D2d N Mo + 2M2* + M2y + 2M2* + 3Afx = Mo + 2M2z + 2M2y + 2M2X + 4MX 2Jd (Space Group 111 - P42m) =5 1 Vibrational contribution of equivalent sets of atoms on site 2W1) ^B). Us C.D) Cl(8) 2M2 + Afd + 3Afx = MQ + 2M2V + 4M2 + 4Md + 8MX CM CM CM 1 1 1 Minus nongenuine vibrations -1 -1 -2 R IR, R IR, R IR, R Spectral activity R R IR, R IR, R 11 Herzberg identifies this element as ra4. 89
(Space Group 47 — Pmmm) ~ Vh Minus nongenuine Vibrational contribution of equivalent sets of atoms on site vibrations Spectral activity C2VM C8D) ; axis y axis x axis xy plane zx plane yz plane £^(8) N = MQ -f 2M2z + 2M2l/ + 2M2x + 4Myz + 4MZX + 4M^ + SMX
C3 (Space Group 143 - P3) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity c8(i) A E N = Mo -2 -2 IR, R IR, R (Space Group 174 - P6) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity Csh(\) C,B) C,C) qF) A' E' A" E" N M3 + 2Mh + M3 + 2Mh + M3 + Mh + 2M3 + 3Mh + R IR, R IR R Czv (Space Group 156 — PSml) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity Cav C3v(l) Ai Mo 4 E Mo 4 N - Mo + - 1MV -f Mv -\ -3Mv-\ -3AfrH qF) - 37kf, - 3AT, - 6MX - 6MJ -1 -1 -2 IR, R IR, R 91
D3 (Space Group 149 - P312) Dz E N Vibrational contribution of equivalent sets of atoms on site JJz\i) C3vw °2Wy uivD; Mo + M9 + ZMy ^/f _i_ j^/£ _i_ 2-/V^o H~ 3Ai"i Mn + 2AfQ + 3Afo + 6M-, = M0+2M3+3M.+ 6M, Minus nongenuine vibrations -2 —2 Spectral activity R IR IR, R (Space Group 162 — P3\m) = S6v Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity ,A) CzvB)* C2F) CsF) qA2) Ms,, + M2 + 2Md + 3M! R 2M2+ Md+ 3M1 -1 M2- R Mo + 71^3^ + 2^2 + 2^^^+ 3MX —1 IR Mo + Af3v + 3M2 + 3Md + 6MX -1 IR iV = Mo + 2M3^ + 6M2 + 6Md + 12MX ' Herzberg identifies this element as m6 [12]. 92
Minus nongenuine Vibrational contribution of equivalent sets of atoms on site vibrations Spectral activity C3^B) C2VC) h plane v plane ^A2) A[ Mzv+ M2v + 2Mh + 2MV + 3 Mi R 4 M2V+ 2Mh + Mv + 3M± -I E' Mo + M3V+2M2V+ 4Mh + 3MV + 6Afx -1 IR, R A'[ Mh + Mv + 3M-L 4 Mo + M8t,+ M2V+ M^ + 2MV + 3MX -1 IR ^ M3V+ M2V+ 2Mh + 3ATV + 6M1 -1 R AT = Mo + 2M3V + 3M2V + 6Mh + 6MV s
C4 (Space Group 75 — P4) A B E N Qa 1 N n 4i> A Bx B* E N Vibrational contribution of equivalent sets of atoms on site Q(l) CxD) MQ + 3MX Mo + 3M2 = Mo + 4M2 Qa (Space Group 83 — Vibrational contribution of equivalent sets of atoms on site C47i(l) QB) CsD) q(8) 2Mh + 3Afx Mo + M4 + MA + 3^i 0 • 4 ft ' 1 = Mq + 2Af4 + 4Af^ + 8M^ CAv (Space Group 99 — Vibrational contribution of equivalent sets of atoms on site C.D) C4v(l) y plane t/plane ^(8) Mo + 2MV + 2Md + 3MX M.v + 2A/^ -f- 3AjT^ Mo + 3MV + 3Md + 6M1 = Mo + 4MV + 4Md + 8Mt Minus nongenuine vibrations -2 -2 P4/m) Minus nongenuine vibrations -1 -1 -1 P4mm) Minus nongenuine vibrations -1 -1 -2 Spectral activity IR, R R IR, R Spectral activity R R R IR IR Spectral activity IR, R R R IR, R 94
Z>4 (Space Group 89 — P422) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity Z>4A) C4B) Cgaxi E N Af£ Mo + M4 Mo + 2M4 j + 3Afx -2 -2 R IR R R IR, R Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations C2(S) C^axis Cs(8) Spectral activity 2Md 3M1 6M1 -1 R -1 -1 -1 IR IR R R N Mo Herzberg identifies this element as 95
D4h (Space Group 123 — PAjmmm) Minus nongenuine Vibrational contribution of equivalent sets of atoms on site vibrations Spectral activity C2VD) C,(8) Cj axis C2 axis h plane v plane d plane CjA6) R -1 R R -1 R + M4v+ Mzv+ M2v + Mh + 2MV + 2Md + 3MX ~1 IR M2v + Mh + Mv + 2Md 4- 3MX M'2v + Mh + 2MV + Md + 3MX + M4v + 2MgV -f 2M^ + 4Mft + 3MV + 3Md + 6Mt — 1 IR N = Af0 + 2M41, + 4M2-y + 4M^ + 8ATA -f 8M^ -f SMd M2v + Mgv + Mfzv -f Afgv 2M^4 ^2-y "^ " M'2'v -+ ■ ^ 4 Mlv 4 4 ■ 2M2v 4 ■ 2Af -4 • 2AjT -4 ■ 2AfA H ^ H - a4 - - Mh - ■ ^Mn ~ - 2MV 4 - Mv 4 h 3MV 4 h Mv 4 h Mv 4 h 2MV 4 h 3MV 4 ~ Jma 4~ - 2Md 4- - 3Mrf + - M^ 4- - 2Md 4- h 2Md 4- h Afd 4- - 3Md 4- 3M1 3MX 6MX 3Afx 3MX 3Mi 3MX
(Space Group 81 - Pi) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations C2B) qD) Spectral activity A B E N h M2 + 3Afx h 2M2 + 3Af2 h 2M2 + 4MX -1 -1 -2 R IR, R IR, R Vibrational contribution of equivalent sets of atoms on site C5AA) C5B) CsE) Minus nongenuine vibrations Spectral activity A" N Mo Mo = MQ ZMh+ 3M1 Mh+ 3M1 Mh+ 3M1 Mh+ 3M1 R IR R IR R 2M5 + 5Mh \0M1 97
A, Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Specjral vibrations activity csE) q(io) N MQ + 2MV Mo = Mo 3MX 1 6M1 -1 IR, R -1 -2 IR, R R Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity CBB) C2E) Mo M5 M5 6M1 R IR IR, R R = Mo + 2M5 + 5M2 98
Minus nongenuine Vibrational contribution of equivalent sets of atoms on site vibrations Spectral activity Dbh{\) C5vB) C2vE) h plane v plane CxB0) A\ Mxv + M9/» -f %Mh + 2Mn -f 3M, R "PI j\/f _i_ iVjTc ~\~ 2^Wo ~ ^fyfjt ~\~ 3^A. —I— GiV^fi 1 IR E'2 2M2V + 4Mh + 3M^ + 6M2 R ^4'i AfA + Mv + 3M± A'2 Mo + M5v+ M2V+ Mh+ ZMV+ 3M1 -1 IR E'[ M5v + M2V + 2Mh + 3MV + 6Ma — 1 R j\T = Mo + 2Af5v + 5M2v + 10MA + 10Mv -
CQ (Space Group 168 - P6) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity c6(i) A B Mo Mo -2 IR, R -2 IR, R R N = Mo (Space Group 175 — P6/m) C6; Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity C6B) CsF) Mo 2Mh + 6Mh + -1 -1 -1 -1 R R R IR IR N 100
C6v (Space Group 183 — P6mm) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity v plane d plane 1MV 3M1 6M1 -1 2 IR, R IR, R E2 3MV N = Mo + 6MV £>* + 3A + 6A (Space fa + 6M1 Id + 12M1 Group 177 — R P622) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity C2F) '2axis Cjaxis qA2) -Y Mo = Mo + 2M6 fg + 2Mj + 3Afj_ -2 ^2 + M2 + 3M1 f' + 6M" + 12M. R IR IR, R R 101
(Space Group 191 — PS/mmm) Minus nongenuine Vibrational contribution of equivalent sets of atoms on site vibrations Spectral activity C2vF) C,A2) D6h(\) C6<yB) Cgaxis Cg'axis h plane v plane d plane CxB4) ^v h V d t Kv + Kv + 2MA + 3MV + 3Md + 6Af! -1 R Alg MQ + M'2V + M2'v + 2Mh + 2MV + 2Md + 3Afx 4>, MJ, 4- Mj, + 2MA + Mv + Md + 3MX J?lg ^ M^ + M^ + Mv + 2Md + 3MX 3MV + 3Md + 6MX R AZ "" "^ ^ -f- Mv + Md + 3Mt J? A/' -f- Af" -4- 2Affc -4- 2 A/ -4- iW^» -4- 3JM Bo«, ML, + Afo« 4- 2Af», 4- Mn + 2Ma 4- 3Af, jEi«, A/n 4* Me 4* 2Afo« 4" 2A^O« ~{~ 4Af», 4* 3Af4, 4~ 3A/,» + 6Aft — 1 IR JV = Af0 + 2M6 4- 6M'2V
= Czi (Space Group 147 — P3) A, M3 + M3 Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity __ — _ _ Mx -1 R Mx -1 IR Eu* MQ + M3 + 3MX — 1 IR iV = Mq + 2Af3 + 6Afj * Herzberg identifies ^4M as Bui Eg as £y, and Eu as £'lM. Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity j j^ -1 IR -2 IR R Ez M4 + 3MX R N = Mo + 2M4 + 8MX Cn: general case in which n is an odd number > 5 (^ 00) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity Cn C»0) Ci(») A MQ + 3M1 -2 IR, R £x Mo + 3MX -2 IR, R £9 ZM, R *1 *8A) Mo- Mo- C4B) M4- f M4 - f M4 - f- 3MX r* 3MX f- 3MX 3M1 iV = Mo + nMx 103
Cnll: general case in which n is odd > 7 (^ oo) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity Cnn{\) Cn{2) Cs(n) Af A" Mo Mn + 2Mh Mn+ Mh Mn+ Mh+ 3M1 3M1 h+ x 2Mh+ 3M, Mh+ 3M± 2Mh+ 3M1 Mh+ ZMX 1 1 1 1 R IR IR R R E(n-l)/2 N = Mn 2Mh 3M, Mh+ 3M1 2Mn + nMh 2nM± Cnv: general case for odd w's in which n > 7 (^ oo) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity Mv+ 3M1 3MV+ 6MX 3Af,, + 6Af, -1 IR, R -1 -2 IR, R R 2nMx 104
Dn: general case in which n is an odd number > 7 (^ oo) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity Dn Dn{\) CnB) C2(n) C±[2n) Ax Mn+ M2 + %M1 R A2 Mo + Mn + 2M2 + 3MX -2 IR Ex Mo + Mw + 3M2 + 6Afx —2 IR, R 2M5 c?: general case in which n is an odd number > 5 (# 00) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity Elg Elu E2g E2u Mo + CnvB) Mnv + Mnv + Mnv + Mnv + C2B«) ^2 + M2X 2M2 + 3M2 + 3M2 + 3M2 + 3M2 + CsBn) 2Md + MI + 2Md + 3Md + 3Md + 3Md + 3M, 3m\ 3M1 —1 o.Ax-f — 1 6^X-| — 1 R IR R IR R Mo + 2Mnv + 2«M2 + 2nMd + 4nM1 105
§5 Dnh: general case in which n — odd number > 7 (^ oo) Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations Spectral activity Dnh(l) Cnv{2) C2v(n) h plane v plane Mnv + M2V + 2Mh + 2MV M2V + 2Mh + Mv -1 R Mo + Mnv+ M2V+ Mo + Mnv + 2M2V+ 2Mh M2 6M1 IR IR R R K K N 3MV + 6M1 3Mm + 6M, "I 2 2nMh + 2nMv
Cn: general case in which n is an even number > 8 (^ oo) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity A B Ei Mo- MQ - MA*! 3M2 hSMx IR, R IR, R R Enf2- N = Mo 3^f1 E(nfz-l)g E(nlz~l)u Cnft: general case in which n is even > 8 (^ oo) Ag Au Bg K E2 Vibrational contribution of equivalent sets of atoms on site C«kV) CnB) C,(«) C^n) Mn+ 2Mh+ ZMX Mo + Mn+ Mh+ 3M1 Mh+ ZMX 2Mh+ 3MX Mn + Mh + 3M1 Mo + Mn+ 2Mh+ 3M1 2Mh+ 3M1 Mh+ 3M, Minus nongenuine vibrations j -1 -1 -1 Spectral activity R IR ... R IR R h 2Mh+ X 3MX Mo + 2Mn + nMh + 2nMx a When (n/2 — 1) is odd, then a — 1, 6 = 2; however, if nj2 — 1 is even, then « = 2, *= 1. 107
Cnv: general case for even w's in which n > 8 (but ^ oo) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity Cnv Cnv(l) v plane d plane C1Bn) A± Mo + 2MV + 2Md + 3^ — 1 IR, R 4a Mv + Md + 3MX -1 £2 Mv + 2Md + 3Af2 E± Mo + 3MV + 3Md + 6Mj_ -2 IR, R £o 3M« + 3M^ + 6M, R 3MV iV = Mn + »Af« ^: general case in which n is an even number > 8 (^ oo) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity C2(n) Dn(l) Cn{2) C^axis C^axis Cx{2n) Bx B* Ex ^2 *3 Mo - Mo - Mn + \- Mn+ 2 2 t- 2MK + 2 M2 + M2 -f- !Mg + 2Mg + Mg + 2Mg + IMg + Mg + \M'% + 3Afg + ;m^ + 3M'l + fM^ + 3Ml + R IR IR, R R 108
general case in which n is an even number > 6 (=fi oo) Dna A Bi Ei E3 E5 En-1 N Vibrational contribution of equivalent sets of atoms on site Dnd{\) CnvB) Mnv- Mo + Mnv ■ Mo + Mnv MnV = Mo + 2Mnv C2Bn) C2 axis CsBn) C^ i- M^+ 2Md + 2Mf2 + Md + M'2 + Md + + 2M'2 + 2Md + 3^2 + 3Md + 4- 3Mg + 3Md + 3Mf2 + 3Md + 3Mg + 3Md + 3^2+ 3^ + -f 2wMg + 2nMd + - Minus nongenuine iD») 3Mt 3^ 3M7 3MX 6MX 6M1 6M± ^nMx vibrations -1 -1 -1 -1 Spectral activity R IR IR R R ...a a For n > 6 the character of the polarizability tensor should be determined for each point group. See [11] for details. 109
Dnh\ general case in which n is even and > 8 (^ oo) A* A, eZ Mo Mo Vibrational contribution CwB) ^n + C2 axis C2 axis • AfL + ^2tf M2v + Af2t, of equivalent sets of atoms on site h plane + 2A4- C.B») z; plane f 2M^ f Mv (/plane CxD«) ] + ^+ 3M^ + 2Md + 3M, + Md + 3^rx + Md + 3MX + 3Md + 6M! Minus nongenuine vibrations - Spectral activity R IR R IR
E2g 2M'%V 4- 2M%V + 4Mh + 3MV + 3Md + 6M2 E2u M'%v + Mlv 4- 2Mh + 3MV 4- 3Md + 6M1 E3g M^v + Mly 4- 2Mh + 3MV + 3Md + 6MX ^v + aMlo 4- ^MA + 3MV + 3Md + ^v 4- /AfJ, + cMh + 3MV + 3Md 4- N = AfQ 4. 2Mn 4- nM^ 4- wAf^ 4- 2nMh 4- 2«Afv 4- 2nMd 4- ■■ =!-■ When i is an odd number, a = I, b — 2, c — 4,/= 2; however, if 1 is an even number, then a = 2, £ = 4,/= 1, <r = 2
Vibrational contribution of equivalent sets of atoms on site Minus nongenuine Spectral vibrations activity -1 IR, R = n -2 IR, R R N D, coh Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations Spectral activity Mo 0°° R IR R IR R N = Mo +2Moo T (Space Group 195 - P23) 112 Vibrational contribution of equivalent sets of atoms on site Minus nongenuine vibrations T{\) C3D) CaF) qA2) Spectral activity A E F N = Mo~ M34 h 3Af8M h4M3H - M2 4- - M2 -f - 5M2-f - 6M2 + 3A^i 9M1 ■\2M1 -2 R R IR, R
Td (Space Group 215 — P43m) *i E Vibrational contribution of equivalent sets of atoms on site Td{\) C3vD) C2vF) C2A2) C Ms + M2 + 2Md + Md + M3 + 2M2 + 4Afd + Mo + 2M3 + 3Af2 + 5Md + ?xB4) 3Af, 3^ 6Mt 9MX 9Mi Minus nongenuine vibrations — 1 Spectral activity R R ... IR,R ¥ == Mo 4M3 + 6M2 UMd rft (Space Group 200 - Pm3) N Minus Eg Au Eu Vibrational contribution of equivalent sets of atoms on site M2v + M2v + 2M2v + MQ + 3M2v + C3(8) M3-f M3 + 3Af34 M3 + M3 + 3M3 + C,A2) C ■ 2Mh + - ™h + ■ Mh + ■ Mh + ■ 5Mh + nongenuine vibrations iB4) 3MX 3MX 9MX -1 3MX 3MX 9MX -1 Spectral activity R R R IR \2Mh 0 (Space Group 207 - P432) Minus Vibrational contribution of nongenuine Spectral equivalent sets of atoms on site vibrations activity 0A) C4F) C3(8) C2A2) CxB4) ^4+ M3+ M2+ 3MX M3 + Afa + 3MX M4 + 2M3 + 2M2 + 6MX Mo + 3M4 + 3M3 + 5M2 + 9Mt 2M4 + 3M3 + 5M2 + 9Afx -2 R R IR R N = Mo + 6M4 + 8M3 + 12M2 113
Oh (Space Group 221 — Pm3m) Minus nongenuine Vibrational contribution of equivalent sets of atoms on site vibrations Spectral activity (C'2->C2 kd~>^ C,B4) V ^* i -*~^- .^ Oh Oh(\) C4vF) C8,(8) C2V{12) d plane A plane CxD8) Alg MAv + Mzv + M2V + 2Md + 2Mh + 3MX R ^iw ^ + -^a + 3Afx ^2« M3v+ M21; + 2Md + AfA + 3MX /? A^* 4— A'/' 4- *? A/F 4— A^A/f 4- c>A'/t. 4— 9A^f< W = Mo
/ A F, F2 G H N \ Ag Au Fig Flu F2g F2« Glg Glu Hg H N / 1 Ih<D M + = M + 1 Vibrational contribution of equivalent "A) < M0 + V: equi< C5vA2 M5v M5v 2M5v M5v M5v M5v 2M5v M5v 12M5v -sA2) M6 4 3M5 -f M5 -f 2M5 -| 3M5-j 12M54 tbrational valent sets sets of atoms on site C3B0) - ^3H - 3M3H - 3M3 H - 4M3 H - 5M3H - 20Mg H contribution of atoms on ) C3vB0) C2vC( + M3v + M3v + 2M3v M3v + 2M3v + ^v + 2M3v + 3M3v + 2M3v + V + 2M2v + 3M2v + 2M2v + 3M2v + 3M2v + 3M2v + 4M2v + 3M2v ~» C2C0) ^F0) h M2+ 3MX h 5M2+ 9MX h 5M2+ 9MX h 6MZ + 12MX h 7M2 + 15^^*3^ h 30M2 + 60M1 of site )) CsF0) C1A20; + 2M, + 3MX \ + 3M1 + 4^ + 9MX + 5Mh + 9MX + 4^ + 9M1 + 5Mh + 9Mi + 6Mh + 12M1 + 6Mh + 12KX + 8^ + 15MX + 7^ + 15M1 + 60M, + 120M. n 1 Minus nongenuine vibrations -2 Minus nongenuine vibrations ) "I "I Spectral activity R IR R Spectral activity R - IR - - R 115
CHAPTER FIVE APPLICATION AND SPECIAL CASES Example 1. Ionic crystals containing linear molecular groups. CASE A. The NH4N3 crystal (Figure 6). X-ray information*: Pmna'Du (Space Group 53) Z - 4 and ZB = 4. Site symmetries ~ . . /rr .. ,.N 7 Correlation (Table 14) Wyckoff Schonflies elating site to factor group NH+ g C2 C2h Ca(x) N3 * L. K. Frevel, Z. Krist., A94, 197 A936). 117
ooo-—®—ooo ooo- Figure 6. The NH4N3 crystal. This projection shows only the ab plane. Two of the Nj" ions are parallel to the a(x) axis, whereas the second set of Njj" ions is in the bc(yz) plane. Here the tilted N^" ions in the be plane are represented by the following: ^^^ ( 0 V-nitrogen atom on the ab plane itrogen atom above the ab plane shown ■nitrogen atom below the ab plane shown The position of the NH£ ions is not described. The NH£ ions are not found in the ab plane shown but are present in the crystallographic unit cell. 118
Irreducible Representations of the Ammonium Ion 119 Irreducible Representations of the Ammonium Ion The irreducible representations for the translation, libration, and intramolecular vibrations of NH^" are obtained in the standard way and are listed here: NHJ Ion Translation with ZB = 4 Site C, Correlation £) factor O2(y) group 4 8 Tv) £?c\>> 1 + 0 + = 1 + 0 = 0 + 2 = 1+0 = 0 + 2 = 1+0 = 0 + 2 trans NHJ M = ^ ion Ry ! 1 O D { T> _i Q D Libration, FnH+; Z = Correlation + 4 A + 2S..H ZJ^ factor group 4 l(Rz) 8 1 2 1 2 1 2 1 2 1 + 0 0 + 2 1 + 0 0 + 2 1 + 0 0 + 2 1 + 0 0 + 2
120 Application and Special Gases Summary: = Ag + 2Blg + B2g + 2B3g + AU + 2Blu + B2u + 2B3u ZNH+m° m , ZB = 4; Molecular Symmetry ofNHt ion is Td viba Molecular symmetry Correlation ^ ofNH+ ^ Site symmetry ion T, Correlation C2(V) d Factor group D2h intramol + 5B 2g 5AU 4BS a We have already obtained the irreducible representations for the NH^~ ion, i.e., rHN+ = A1 + E + 2F2. Here we have four NH^" ions; therefore this irreducible representation is multiplied by four, or T^g-H = 4A 4E + 8F2; v-± is the N—H symmetrical stretches, v2 is the degenerate bendings of the HNH bond, i>3 is the asymmetrical stretching of the NH bonds, and v± is the triply degenerate HNH angle bendings. Note the intramolecular vibration in the crystal is far more complex than this simple description for the isolated ion. to To conserve space in some of the following examples, the individual a 's are written atop each ray relating the different species. Correlations Relating D^ to C2h for the Azide Ions Two N^~ ions lie along the a axis in Site a; the remaining two NjJ" ions are found in the be plane in Site b. In Site a the molecular C^ axis is coincident with the C2 axis of the C2h site group and in Site b a C2 axis of the molecule lies along the C2 axis of the
Irreducible Representations for N3 in Site a 121 C^n s^e group- The correlation relating Dooh to CZh can be constructed according to the method given in Chapter 2: Site a: Site b: n, A 2Ag 2~^~ A Z? S~~ A A u -**« ""« £*-> nt *1<,I "t" Irreducible Representations for N3 in Site a Translations of the N3 /<?#, FN-(^««a); ^^ ZB = 2 Molecular Correlation Correlation ^2A symmetry >• Site C2ft > factor P t* Dmh a*»°* °*» group 2 1G;) 4 2(^7;) ntt- trans _ L NJ (Site a) — ^w " ^-°1m i" 4-°2w "r ■ Libration of the N3 /ow, rN-(^«ea)/ «;zVA Z"8 = 2 Since the Ng" ion is linear, there can be no molecular rotation of this ion about the axis containing all three nitrogen atoms,
122 Application and Special Gases i.e., the degree of freedom involving Rz is zero. Molecular Correlation Correlation D* symmetry > Site C*h >- factor II, Intramolecular {Internal) Vibrations, V^-{Sitea); ZB = 2 To determine the number of molecular modes for the N7 ion, we refer to Table 24 and point group D^h, In Table 24 we substitute MQ = 1 and M^ — 1. The irreducible representation of the intramolecular vibrations for one N^ group is rN- = ^ + sj + nuforZ = i. However, ZB = 2, and therefore we multiply the above by two to obtain the correct irreducible representations for the intramolecular vibrations of the N^ ions in Site a in this crystal. Thus P Molecular symmetry Correlation Correlation *actor .. ,T_ >■ symmetry >• group ofionNg, Coo,"* r C^x) 6n v 1 0 V _- -LV 2 2(»1) 2 2(v3) 4 2{v2) a Vibrations are described as different combinations of the v^ symmetrical stretching and contraction of the ions, i>2> as modes involving combinations of the degenerate bending of the ions, and v3, as combinations of the asymmetrical stretch.
Irreducible Representations for N^~ in Site b 123 The irreducible representation for the intramolecular vibrations of the N7 in Site a is B3g +AU+ 2B1U + 2B2u + B3u Irreducible Representations for N3 in Site b .trans Translations of the N3 Ion, r^iSiteb); with ZB = 2 fy Molecular Correlation Correlation symmetry >- Site C9Jl > D G2,av 2h C2(x) factor group \{TZ) , ry) _trans ==Au BZ lib Libration of the N3 Ion, T^-(Sit6b); with Z = 2 Molecular Correlation Correlation °» symmetry y- Site C2ft —— > factor fh group a? 4 2(TX, Ty) ^
124 Application and Special Cases Intramolecular (Internal) Vibrations, T™™^eh); ZB = 2 As already discussed for N^ in Site a, the intramolecular vibrations for N7 in Site b are also given by F2N- =22^" + r Molecular c. _ ^ . .. Site ~ , ,. r actor symmetry Correlation Correlation 1. ,, >• symmetry >■ group ofionN3, c2,<rv n C*W n 2 2(Vl) 2+ 2 2(v3) S+ 4 2(,2) ^u ite 6) = Ag + ^39 + ^« + 2-SlM + 2S2u + B3u Summary of the Irreducible Representation for NH4N3 trans 1 n~ trans NH4 rNH+ pintramol pinteamol pacoust Fcr°ytt = K Ag 0 1 1 1 2 5 0 Ug + *i. 0 2 3 2 0 4 0 "Si, H 0 1 3 1 0 5 0 - 102?2, ■ r for species 0 2 1 2 2 4 0 2 1 0 1 2 5 0 + 11*8,+ + 15 : *lu 4 2 0 2 4 4 -1 *1« +1 B*u 4 1 0 1 4 5 -1 4B -f 2 2 0 2 2 4 -1 ■H*8«
Summary for NH4N3 Molecule K F H oo o 125 Figure 7. The KHF2 crystal. Shown here is the ab(xy) plane. The FHF~ ions are situated in the ab plane; however, the C^ axis of the ions is not parallel to either the a or b axis. The numbers within the circled atom designate the position of the atom in the c plane. case B. The KHF2 crystal. (Figure 7). X-ray information: Dt-h,mcm (Space Group 140). Z = 4, ZB = 2. Atom Site symmetry WyckofF Schonflies Correlation (Table 14) relating site to factor group K H F a d h D C.. 2h First we obtain the irreducible representation for the crystal, disregarding the presence of the covalently bonded linear ion (FHF)~; second we treat the molecular crystal identifying libration and internal vibration of the molecular ion (FHF) ~.
126 Application and Special Cases The total irreducible representation of the crystals must be the same in each of the proposed treatments. Irreducible Representation of the Crystal (disregarding the FHF~ molecular ion) Irreducible Representation of the Translation Pr*118, the Irreducible Representation of the Potassium Ions, ZB = 2 Site Factor Correlation symmetry >- group fy Ty D D 4 2G;, Ty) E = .- .- _- : _- - Summary: IT** = Au + A2u + Eg + Eu Fh?8, the Irreducible Representation of the Hydrogen Atoms, ZB =2 r Site Correlation ractor STOUD symmetry ^ ° °; u 2 2 2 1G-,) 1G",) 1G-.) ^lw —. 5 - A EU 1 2
Irreducible Representation for the KHF2 Crystal 127 Summary: Y%*?* = A2u + Blu + 2EU Tf-71*, the Irreducible Representation of the Fluorine Atoms, ZB -4 f T? Site Correlation Factor fiTOUD symmetry ^ ° r ° D 4 HTZ) At ^— Au 1 4 l(rx) 5X =\r^^~- A2g 1 4 1(T.) 52.--X ~^^^^---5,. 1 1 1 0 1 1 0 2 ■ptrans j ,j tz? iZ? iJFiJ ?z> iOZ? Irreducible Representation for the Molecular Crystal KHF2 Considering the Presence of the Molecular Ion (FHF)- Note that the T^+ns is identical to that derived in the first part. The translation of the (FHF)~ molecular ion is the same as the irreducible representation for the translation of the hydrogen o+,-n™ 4 ~ -ptrans T-itrans atom, i.e., i (FHF)- = 1 H . For the librations and intramolecular vibrations of the (FHF) ~ ion we require the correlation of the molecular point group Dooh to the site group D2h. The C2(z) axis of the D2h site is coincident with a Cz axis of the D^ group. For one-half the ions the C^ axis of the ion lies along the C2(x) axis of the DZh site, whereas for the other half it is aligned along the C2{y) axis.
128 Application and Special Cases Using the method outlined in Chapter 2, the following correlations can be constructed: 2+ 27 Ug Ag C00A Ag Ag + g %Zg ■ ^2g A, B3g Ag + B3g TT-1 A A u -^lu "T" ^3w -"lw I ^2 Since the difference between the two correlations involves only an interchange of the 2 and 3 subscripts of the B species (i.e.3 designation of the x andjy axes is arbitrary), both will give the same final irreducible representations for the librations and intramolecular vibrations of the (FHF)~ ion in the D%h site group and Dih factor group, and either can be used to obtain the final result. Irreducible Representation for the Libration of the (FHF)~ Ion This linear ion has only two degrees of rotational freedom, Rx and Ry. Molecular Correlation Site Correlation Factor symmetry >■ symmetry y group 2 (*«,*, . _ ^ ""^ ~~ 1 1
Irreducible Representation for the KHF2 Crystal 129 The Intramolecular or Internal Vibrations of the (FHF)~ Molecular Ion (FHF)~ Possesses D(X)h Molecular Symmetry Using Table 24 for this ion and substituting Mo = 1 and Mao ^ 1> tne irreducible representation for this ion molecule is r = s+ + s+ + uu. However, there are two molecular ions per Bravais cell; therefore the irreducible representation is multiplied by 2: r = 2SJ + 2Si + 2nw. The following correlation relates the molecular symmetry to the factor group symmetry: Molecular Site Factor Correlation Correlation symmetry >- symmetry 7, >- group D D D n.<S> A2u + Blu + 2EU Summarizing these results, we have the following: 1. The irreducible representation for the ionic crystal KHF2 J. p trans p trans p trans pacoust pcryst 0 0 1 0 Ag Ag 1 0 1 0 Blg 0 0 1 0 Ag-i B2g 0 0 1 0 -Bl9 a^ for Eg - 1 0 1 0 4- B A species 0 0 0 0 -22?, An 1 1 1 -1 + 2, Blu 0 1 1 0 B*u 0 0 0 0 2£lw4 1 2 2 — 1 -4£u
130 Application and Special Gases 2. The irreducible representation for the molecular crystal KHF2 in which (FHF)~ molecular ions are identified ptrans p trans 1 (FHF)~ plib 1 (FHF)~ pintramol ■ (FHF)~ pacoust pcryst 1 total — A, 0 0 0 l 0 Ag r Ag 1 0 1 0 0 + 2A Blg 0 0 1 0 0 2, + B2g 0 0 0 1 0 Bl9-\ H Eg 1 0 1 0 0 for species An 0 0 0 0 0 , + 22?, An 1 1 0 1 -1 + 2j Bin 0 1 0 1 0 *2u + ' B2u 0 0 0 0 0 Eu 1 2 0 2 -1 M2?« The total irreducible representations in parts 1 and 2 derived above are identical. This must always be the case, regardless of whether covalent or ionic bonding is present (we have more to say about this in Example 4 of this chapter). Indeed, only one correlation which relates the molecular ion symmetry to the site group symmetry is correct; however, there are possibilities of other incorrect choice. Should an incorrect choice be made, the total irreducible representation for the molecular crystal will not be identical to the correct total irreducible representation derived from the ionic crystal. This method provides an excellent cross check to avoid errors. Example 2. Identical atoms with different sites: B^C Information: D\d-R^m (Space Group No. 166), Z = 9. site symmetries: Atom 1C 2C 6B 6B Wyckoff notation b c h h Schonflies description c3v cs cs
Irreducible Representation for the KHF2 Crystal 131 It was noted in Table 2 that R type crystal structures may be divided by 3 or 1. We found in the case of a-Al2O3 that Z = 2; therefore, no reduction was necessary. In the case of B^C, however, where Z = 9, we must divide by 3 to reduce the crystallographic unit cell to the Bravais space cell; i.e., Care must always be exercised in the reduction of /?-space groups to the Bravais cell. Since the carbon atoms have different site symmetries, the irreducible representation for the carbon atoms is SiteZ>3d Site C3v and the total irreducible representation for the Bfi crystal The irreducible representation for each site and specific atom in the above equation can be obtained as follows: Site D2d Correlation factor species y group ty species £ C^ 1 1G-,) Ai% A2u 11=1+0 2 2{Tx,Ty) En Eu 2 1=0 + 1 Eu.
132 Application and Special Cases Site CS r Site CZv species y Correlation 1J3d factor group species I ar = UE 2 4 1 i 2 1 1 1 2 1 1 + 0 0 + i 1 + 0 0 + 1 SiteO3v ■En fy tv 24 2(Tx,Ty) 12 1G-,) Site Cs correlation species y > A' j.k factor group species £ A - A2g ^^ F \ A2u c, 1 1 2 1 1 2 2 = 6 = 2 = 4 == 6 = A! 4 0 4 0 4 4 + + + + + + + 0 2 2 2 0 2 = 4A lg 2A2 6Eg 4A 2u Summarizing the above results to obtain the irreducible representation for the crystal, we have rB.Ccryst SiteD3d SiteC3v lEg 6A 2u - Eu
Irreducible Representation for the KHF2 Crystal 133 where racoust - A%u + Eu. Therefore the spectral activity of the jB4C crystal is = 54? + 7£<R) + 545° + 7£<m> + 2A\£> + 242' Example 3. Use of correlation tables for species with separable degeneracy. R2O3-bixbyite structures such as MnaO3. Information: Tl-IaZ (Space Group 206); Z = 16, therefore SITE o ; SYMMETRIES Atom 4R 12 R 24oxy Wyckoff notation b d e Schonflies designation ^6 = CZi Note: As in Case 3, there are two different and distinct sites for the R atoms. Therefore the irreducible representations of the Site SQ Site C2 crystal is T^03 cryst = TR + TR + roxy. The irreducible representation for the different sites and atoms follow: Site Correlation ? j-9 v species y Y _ o-t — ; /7 r ' species 4 C? a^ + a 1 1=1+0 8 2G;, Tv) Eu - -^^^- -Eu 2 1=0+1 3 3 = i + 2a 6 .-. rB = Au + Eu + 3FU a It is to be noted here that the correlation tables given in Appendix III must be modified because of the separable degeneracies of the
134 Application and Special Cases group. The modification involves the addition of a coefficient 2 to the Et species of point group S6 relating Fg and Fu of the point group Tk as follows: Aa+2Eg Note that a forked ( c) ray is used in the diagram above from the Eu to the Fu species to indicate the presence of the coefficient 2. The coefficient 2 appears in the calculation of ay as follows: = 8 = a rE. K. Bm Tabulation of the a% K, = aEu [*-«CEu + (»-Cr% + *»CFa)\, collecting terms av = 1. Th factor group species I x coefficient 1x1=1 1x2-2 Site r SiteC2 correlation species y Th factor group species £ aB 12 24 2{TxiTy) Site C2 5Fa 1 2 3 1 2 3 1 + 0 la + 0 1 + 4 1 + 0 la + 0 1 + 4 Eu.+ 5FU
Irreducible Representation for the KHF2 Crystal 135 a Note that the coefficient 2 is removed for the E species because of the separable degeneracy; therefore the modified correlation table is A A In Appendix III those species that do not use the coefficient 2 are designated by an asterisk (*). roxy, see p. 136-7 for correlation diagram. Therefore to calculate aA f =12= aA{CAg + CEs + CFg + CFg + CFa + CAu + CEu + CFu + CFti + CFJ, collecting terms = aA{\ + 2 + 9 + 1 + 2 + 9} = aA{24} aA =3 Therefore roxy = 3Ag + 3Eg + 9Fg + SAU + 3EU + 9FU SiteS6 SiteC2 rR2O3 crystal = pR _|_ pR + p^ _ pacoust ~ Fu where racoust = Fu. Summarizing the selection rule for R2O3, we have 5£< <0)
* oxy r Site symmetry Ci species y Correlation8 Th factor ** group species £ ~ aA X (coefficient) 72 3G;, Ty, T,) Ag Eg F, K Eu F,, 1 2 3 1 2 3 3 = 3 = 9 = 3 = 3 = 9 = 3 3 3 3 3 3 X 1 X 1 X 3 X 1 X 1 X 3 a The correlation for this is
x (comment) A En A [the coefficient 2 marked with an asterisk (*) is disregarded] 3^4 [note the ray for A to Fg and Fu has three prongs ( — three coefficient] A Eu A [the coefficient 2 marked with an asterisk (*) is disregarded] Fn, ZA (same as Fg species) -e-) to indicate the presence of the
138 Application and Special Gases We realize it is possible to write out formally an equation that generates all the ayys regardless of the presence of separable degeneracy; however, the additional coefficients, often 1, of the equation distracts from the simplicity and ease of applying the correlation method. Therefore we have chosen to discuss its application when separable degeneracy occurs as a special case and to provide these examples to illustrate its alternate application. Example 4. M3A15O12-Garnet Structure. Information: 0™- 7O3d(Space Group No. 230), Z - 8, ZB = 8/2 = 4. SITE SYMMETRIES Correlation Wyckoff Schonflies table to be used Atom notation designation (see Table 14) Direct Direct Direct case 1. M3A15O12 as an ionic crystal. In this treatment no consideration is given to the possible presence of (A1O4) or (A1O6) molecular groups. Without some chemical knowledge or experimental information regarding the presence of covalent bonding it is meaningless to discuss group librations and translations. The following irreducible representations are derived for the ionic crystal, disregarding any possible covalent bonding: 8A1 12 M 12 Al 48 O a c d h
Irreducible Representation for the KHF2 Crystal 139 Site S6 TM, 8 Al Atoms in Site S6 Site symmetry correlation. species y factor group species £ ar = 8 1G-.) 16 2(TX, Tv) 1 = 1 + 0 1 + 0 0 + 2 1 + 2 1 +2 Site S6 Tai = Alu + A2 TM, 12 M Atoms in Site 2EU + 3F1U + 3F2u Site Symmetry Correlation^ ; species y factor group species £ Cc aBi + a aB> 12 12 1G-,) 12 1G;) 0 + 0 + 0 1+0 + 0 i+o + o 1 + 1 + 1 0 + i + i 0 + 0 + 0 1+0 + 0 1+0 + 0 1 + 1 + 1 o + i + i = A2g +Eg+ 3F lg 2F ig 3F lu 2F 2u
140 Site 6*4 TA1? 12 Al Atoms in Site S4 Application and Special Cases Site symmetry Correiationv P ty species y If) 1 / rj-i \ 7") 24 2G;, 7;) ^.= ^§^sT" \ oh factor group species £ A. — A2q ^E9 ~~ Flg "^ F29 ^ A\u \ A2u V\ U \ s lw Ft* 1 1 2 3 3 1 1 2 3 3 0 = 0 + 1 = 1 + 1 = 1 + 2 = 0 + 3=1 + 1 = 1 + 0 = 0 + 1 = 1 + 3=1 + 2 = 0 + 0 0 0 2 2 0 0 0 2 2 TA1 = A2g +Eg+ 2Flg + 3F2g + Alu + Eu + 3Flu Summarizing a^ for species, we have the following: Site £6 PA1 = PM = Site ^4 PA1 = pa _ x oxy pacoust rcry vib == 0 0 0 3 0 34 •^2ff 0 1 1 3 0 ? + E9 0 1 1 6 0 5^2° 0 3 2 9 0 + I F*9 0 2 3 9 0 8E™ 1 0 1 3 0 + 14J ^2M 1 1 0 3 0 10£lo) + 2 1 1 6 0 ■ 17^R 3 3 3 9 -1 r ) _|_ 3 2 2 9 0 1 BJ?@) ior2u °Site table summarized on p. 141.
roxy All Oxygen Atoms of General Sites Cx Site symmetry Q species y Correlation Oh factor group species £ U x (coefficient) 144 3G;, Ty, Tz) 1 1 2 3 3 1 1 2 3 3 3-3 3-3 6-3 9 = 3 9-3 3-3 3-3 6 = 3 9-3 9-3 X X X X X X X X X X 1 1 2 3 3 1 1 2 3 3 Foxy — oAx 3A 2g 6Eg + 9F U 9F 2g 3Alu + SA2u + 6EU + 9Flu + 9F iu
142 Application and Special Cases case 2. M3A12(A1O4) 3. Here we have the same crystal structure as in Case 1 of this example, except that covalently bonded groups AIO4 of Td symmetry are identified. How do the selection rules change ? Indeed, there are now the external librations and translations of the A1O4 group as well as its internal vibrations or intramolecular modes. The following example will answer this question: 1. FM is the same as in Case 1, Example 4. 2. F^*6 6*6 is the same as in Case 1, Example 4. 3. Therefore the irreducible representation for the external vibration (libration and translation) and internal vibrations must be calculated for the A1O4 group. 1 A104 fk 19 1Z 24 : 1 \-K-z} Site symmetry species y A ■ *N oh Correlation factor group species £ A "^-^ A V^V ^^^\ 9 <\F±u 1 1 1 2 3 3 1 1 2 3 3 H "a i i i — i 0 = 0 1 = 1 3 = 1 2 = 0 0 = 0 1 = 1 1 = 1 2 = 0 3 = 1 a7 1 A \ " + o + o + 2 + 2 + o + o + o + 2 + 2 = Alg +Eg+ SFlg + 2F 2g 2u Eu + 2F lu 3F 2u
Irreducible Representation for the KHF2 Crystal 143 pjntern vib 1 A104 Moleculara Correlation (f7) Td /1O\ A 12 B4) E - - - - - -1 - - G2) F2 — 36— Site Correlation A — E ^^^\^\N^- N oh factor group A9 Z~'F2g \^Alu \ A2u ^ Eu ^Flu 1 i i 2 3 3 1 1 2 3 3 H 2 Q o 5 6 7 3 2 5 7 6 a The irreducible representation given in Chapter 4 for NHj (p. 83) is identical to that for (A1O4). rmtern vib = j^ + 3^ + 5^ + ^ + lF2g + 3Alu + 2A2u + 5EU + 7Flu + 6F2U Site S^ rAiao4S is e(lual to rAi derived in Case 2, (p. 139). Summarizing the irreducible representation derived atoms, we have the following: rM Site S6 Tai — ■plib.. AIO4 pintern vib AIO4 ■p trans 1 AIO4 — pacoust p « total vib * Alg 0 0 1 2 0 0 lAffi A29 1 0 0 3 1 0 + 54 1 0 1 5 1 0 g> + 3 0 3 6 2 0 8£CR \JX-J g 5 for 2 0 2 7 3 0 '> + species: 0 1 0 3 1 0 14F{0> 10i4° -^2u 1 1 1 2 0 0 >+ J K 1 2 1 5 1 0 :if^ Fiu 3 3 2 7 3 -1 ">+ 1 F2u 2 3 3 6 2 0
144 Application and Special Gases Here we see the same total irreducible representation obtained in Case 1, summarized on p. 140; because of the co- valent bonding, however, some motions are now identified as librations, translations, and intramolecular vibrations of the A1O4. This example illustrates that the total irreducible representation must be the same regardless of the presence or absence of covalent bonding in certain groups. case 3. Case 3 considers the possible structure M3A13(A1O6J with A1O6 covalently bonded groups of Oh symmetry. A summary of the irreducible representations follows: ■ptrans 1 (A106) (■A-lOg) T^int6rn vib pacoust vib Aotal vib Al9 = 0 - 0 = 0 = 1 — 2 = 0 A2g 1 1 0 1 2 0 + 5A + ^ 1 1 0 2 4 0 Vs 3 2 0 3 6 0 OJZlg for species 2 3 0 3 6 0 0 1 1 0 3 0 4/r(o: ^2M 1 0 1 0 3 0 ) + 1 ) _j_ j K l l 2 0 6 0 3 3 3 0 9 -1 ^2W 2 2 3 0 9 0 Again this total irreducible representation is the same as that found in Cases 2 and 3 of Example 4 on pp. 140 and 143. We are now describing different librations and translations in intramolecular vibration of the (A1O6) group. These examples demonstrate the importance of knowing the nature of the bonding in a crystal for describing the vibrational modes.
Irreducible Representation for the KHF2 Crystal 145 Example 5. Polymers: In the preceding applications of the Winston-Halford* site group approach which utilizes the correlation method it has been assumed that the center of gravity of a molecule is located on a crystallographic special position of the space group. The properties of this special position are unique in that the point group operations which leave this position invariant form a group that is a subgroup of both the space and molecular groups. For an infinite chain polymer, however, it is evident that the center of gravity position is meaningless; therefore an "axis of gravity" point must be selected in the unit cell. The axis of gravity, which must be used instead of the center of gravity in polymers, can contain several operations that are not contained in the various molecular point groups, e.g., translation, glide reflections, and screw rotation. Each of these operations will leave the axis of gravity unchanged. The complete set of all the operations that leave the axis of gravity invariant constitutes the site group of the line group which may or may not be isomorphous to any subgroup of the space group. It will, however, be isomorphic to some subgroup of the factor group of the crystallographic space group. To begin the derivation of the selection rules for polymers we must first consider the polymer as an isolated infinite chain and classify its symmetry according to a line group analysis. To begin this procedure the line group is first correlated to the polymer site group and immediately followed by the correlation of the polymer site group to the factor group of the crystallographic space group. Both Tobinf and ZbindenJ give a very good discussion on the theory of line groups and therefore it is not repeated herein. * H. Winston and R. S. Halford, J. Chem. Phys. 17, 607 A949). t M. Tobin, J. Chem. Phys. 23, 891 A955); J. Mol. Spectry. 4, 349 A960). % R. Zbinden, Infrared Spectroscopy of High Polymers, Academic, New York, N.Y., 1964.
146 Application and Special Cases data: D£-Pn case 1. Crystalline polyethylene. X-ray (Space group 62).* There are two chains each consisting of —(CHa—CH2)— units passing through the crystallographic unit cell. The symmetry elements of the planar zig-zag chain of polyethylene are shown in Figure 8a. The line group consists of the following operations: translations along the chain axis, a (a) Polyethylene V x(a) , <rfl(xz) f\ a(xy) C2(x) cr(xy) C2(x| z(c) y(b) H ---c|(z) (b) Polyvinyl Chloride cr C2(z) \\Jt cr(xz) 4 H Cl C2(z) cr(xz) Figure 8. {a) A line group representation for crystalline polyethylene. The line group described within the brackets [ ] possesses the following elements of symmetry: a C2(y) rotation axis parallel to they axis which passes through the center of the G—G bond; a center of inversion, i9 at the midpoint of the G—G bond; C2(x) rotation axis parallel to the x axis and passing through the carbon atoms; a(xy) reflection plane parallel to the xy plane and passing through the carbon and hydrogen atoms; and the identity element E. (b) A line group representation for crystalline polyvinyl chloride. The line group described within the brackets [ ] has the following elements of symmetry: E, the identity; C2(z) rotation axis parallel to the z axis and passing through the carbon atoms of the GH2 group; a reflection plane a{xz) parallel to the xz plane and passing through the hydrogen, chlorine and carbon atoms of the GHC1 group. * G. W. Bunn, Trans. Faraday Soc. 35, 483 A939).
Irreducible Representation for the KHF2 Crystal 147 center of inversion, i; a glide reflection, ag{ yz); a twofold screw- rotation, Csz{z); two reflection planes, ct{xy) and a{xz); and two twofold rotation axes, Cz(x) and C2{y). These eight operations form a group of order 8 and this group is isomorphic to the DZh point group. Referring to Figure 8a, we can describe the local symmetry of the carbon and hydrogen atoms of the {CH2—CHa} unit as follows: 1. Two carbon atoms contain the operations E, C2(x), a{xy), g(xz). These are the operations of the CZv point group; therefore the site symmetry of the carbon atoms is isomorphic to CZv. 2. Four hydrogen atoms contain the operations E, a{xy). They are isomorphic to the point group Cs. 3. Correlations to be used are found in the following manner: C2v -> DZh. The C2 axis of the CZv group is coincident with the Cz(x) o(DZh; therefore CZv —-> D C2(x) Zh- Cs —* D2h. The cth plane of Cs is the same as the <y{xy) plane of D2h; therefore Cs > D2n. For carbon atoms Z = 2 in the line group the irreducible representation is derived as follows: 2 ur.) ^^ ^o 1 = 1 + 0 + 0 f i + o 2 urj 5, c - \ ^ -52O i = o+o+ l f o + o 2 ur.) *,d "-\ ^ o = o+o + o f o + l f 1 + 0 f 0 + 0 ^carbon (line group) = ^g + -Si9 + 52i7 + £lu + £2m + B3u
148 Application and Special Gases For the hydrogen atom Z = 4 in the line group the irreducible representation is r «A' 2=2 + 0 2=2 + 0 1 = 0+1 1 = 0+1 1 = 0+1 1 = 0+1 2=2 + 0 2=2 + 0 ■^hydrogen (line group) ~ ^4g + 2Blg + B%g + BZg + Au + Blu + 2B2u + 2BZu The total irreducible representation derived for the carbon and hydrogen atoms of the line group is line group carbon (line group) ~r~ x hydrogen (line group) Regroup = 3 A* + 35X, + 2B2g + Bzg + Au + 2Blu + 3B2u + 3B3u The irreducible representation of the translations for the line group in this species of DZh is ■ptrans r> i p i_ r> 1 line group ~ -°lu "t" ^2W "T ^>3u The only rotation possible is about the chain axis, i.e., the z axis. Since Rz is contained in the Blg species of D2h, the libration of this polymer will be plib _ D line group ^9
Irreducible Representation for the KHF2 Crystal 149 Therefore the irreducible representation for the intramolecular vibration can be obtained for the line group: pintramol vib ptot ptrans plib A line group line group l line group line group = 3 Ag + 2Blg + 2Big + B3g + Au + Blu + 2B2u Next we must determine which elements of the factor group D2h of the space group D^h leave the axis of gravity invariant. The factor group operations include E, Cl(x), C2{y), Cs2(z), 0g(xz), <yg(yz), <y(xy), and i. Referring to Figure 8a, we recognize the invariant operation as E, Cs2(z)> tf(ry), and i. These operations, E, C2y a{xy), and i9 are isomorphic to the C2h point group; therefore the site group of the polymer is CZh. The correlation that relates the line group D2h to the polymer site group CZh to the D2h space group is C2(z), since the C2(z) axis is the coincident axis in all these groups. The correlation is D%h line group ——> C2h site > D2h factor group. Therefore the irreducible representations are derived as shown on page 150. Tfcot - 6Ag + 6Blg + 3B2g + 3BBg + 3AU + 3Blu + 6B2u + 6B3u There are no pure rotational modes of the polymer chain in the three-dimensional case: coust pintramol vib __ ptot pa = 6Af + 6Bfg + 3Bf9 + 3Bfg + 3^2 + 2Blu + 5B2u + 5BZu case 2. Syndiotatic crystalline polyvinylchloride. X-ray data*: DH-Pbcm (Space group No. 57) with two chains each * G. Natta and P. Gorradini, J. Polymer Sci. 20, 251 A956).
ptot a line group 3 3 2 1 1 2 3 3 X X X X X X X X X Number of chains per unit cell o 2 = 2 = 2 = 2 = 2 = 2 2 = 6 6 4 2 2 4 6 6 Line group Polymer site group C9h Factor group of space group 6 6 3 3 3 3 6 6 Previously derived on page 148. Note the degrees of freedom/7 for each species is the rptot i v (Number of chains) 1 line group/ X |per unit ceU |-
Irreducible Representation for the KHF2 Crystal 151 —(CH2CHC1)— in unit cell. The symmetry elements shown in Figure 8b include the identity £, glide plane ag{yz), mirror plane <y{xz) through the CHGl group and twofold axis Ca(z) bisecting the CH2 group. The operations form a group iso- morphic to C2v. Local symmetries for the atoms of the line group are the following: Atoms Carbon (CH2 group) Hydrogen (CH2 group) Carbon (CHC1 group) Hydrogen (CHC1 group) Chlorine (CHC1 group) Operation leaving atom-invariant E,C, E E, a E,a E,a Symmetry of atom in equivalent set c, cs cs cs Correlation needed direct direct a(xz) a(xz) a(xz) Irreducible representations of line groups: For carbon atoms of CH2 group Z = 2 r Line group Co,, ar 2G;, Ty) B =_ . . . _ ~ ~ B9 ■ C(CHa) = A1 2B1
152 Application and Special Cases For hydrogen atoms of CH2 group Z = 4 Line group fy ty C"i C2v #£ 12 3G;, Ty, T,) A B1 B, 3 3 3 3 = 3^! + 3A2 + 3B± + 3B2 In the irreducible representations for carbon, hydrogen, and chlorine of the (CHCl) group the symmetry of all six atoms is Cs; therefore the derivation can be combined as follows: Line group a{xz) ' f-i 12 2(Tx,Ty) Ar ^__ A± 6 -i4a 3 6 1C",) A"=--W~' ^^ B± 6 *~ - x>2 ^ GHC1 ~~* °^1 I ^^2 ~T OjD! -j- Ox>2 Combining the above to obtain the total irreducible representation, pt0t P ! p _1 P we have rtot 1A/4 I 1 A i 11Z? I QD Writing the irreducible representation for the following translations and librations, ptrans = At + B± + B2 Flib = Bx (rotation about the polymer chain or y axis)
Irreducible Representation for the KHF2 Crystal 153 we obtain the irreducible representation for the intramolecular vibrations of the line group as before: pintramol vib __ ptot ptrans plib pintramol vib = for the line group of syndiotatic crystalline polyvinylchloride. The D2h factor group operations of the space group which leaves the axis of gravity of the polymer chain invariant are the identity element E, a. mirror plane ct(xz)> a glide plane ag{yz)> and a twofold axis Ca(z). These symmetry elements are from the C2v point group. Here we find a unique situation in which the symmetry of the line group C%v is the same, i.e., homomorphic, to the polymer site symmetry. Note from Figure 8b that the C2(z) axis of the line group is coincident with the Cz(y) axis of DZh\ therefore the correlation is polymer site The irreducible representation for the intramolecular vibrations in crystalline syndiotatic polyvinylchloride are derived as shown on page 154. As derived before, racoust n I p i n and = ptot _ pacoust (there are no Hbrations for the infinite polymer chains) Therefore the irreducible representation for syndiotatic crystalline polyvinylchloride is intramol vib = 10^R + ggR + y^R + 1A°U
iine group Number of chains per unit r Line group Polymer site group CJv) Factor group of space group D 2h 10 x 2 7 x 2 11 x 2 8 x 2 20 14 22 16 B, 10 8 7 11 7 11 10 8 -not 7B 2g UBSg + 7AU UBlu + 10B2u + 8BSu
Irreducible Representation for the KHF2 Crystal 155 case 3. Helical molecules. The IR and Raman selection rules for polymers possessing helical symmetry have been discussed by Higgs,* by Liang and Krimm,f and by Tadokoro.J The symmetry of a helical chain may be treated by using the cyclic factor group CB7rmjn) or the dihedral factor group DB7rm/rcK where n is the number of monomer units per m turns. These factor groups are isomorphous to the point groups Cn and Dn, respectively. Type 1. Crystalline isotatic polypropylene. X-ray data§: 3(—CH2—CH—) units per one turn of helix. Factor group: I CH3 CBtt/3) which is isomorphous to C3. The local site symmetries of all the atoms are Cx (i.e., no atoms lie on the C3 axis). r Atom symmetry Factor group symmetry c. 81 3G;, Ty, T.) 27 27 x, Ty) rtot = ptrans = Rotation can occur about the helical axis only: .-. rrot = a * P. W. Higgs, Proc. Roy. Soc. {London) 220A, 472 A953). t C. Y. Liang and S. Krimm, J. Chem. Phys. 25, 563 A956). % H. Tadokoro, J. Chem. Phys. 33, 1558 A960). § G. Natta and P. Corradini, Nuovo Cimento 15, 40 A960).
156 Application and Special Gases The intramolecular vibrations are found by subtracting the rtransand rrotfrom Ttot: Tintramol vib = 25A + 26E Type 2. Crystalline polyethylene oxide. X-ray data*: 7(—CH2CH2—O—) units per two or five turns of the helix. Factor group: Z)Dtt/7) or D{\QttJ1) for two and five turns of the helix, respectively. Both factor groups are isomorphic to ZO. The local site symmetries are Atom Site symmetry C's H's O's For oxygen atoms of local symmetry C2 the correlation is the following: r 7 14 f HT.) 2(TX, Tt Oxygen symmetry 4 Factor group symmetry D7 4 1 2 3 3 3 = 0 - 1 - 1 - = 1 - f o f 2 f 2 f 2 f 2 roxy =AX+ 2A2 + 3E± + 3E2 + 3E3 The correlation for the carbon and hydrogen atoms on general sites C1 is shown on the facing page. * H. Tadokoro, Y. Ghatani, T. Yoshihara, and S. Murahashi, Makromol. Chem. 73, 109 A964).
Symmetry of carbon atoms r Factor group symmetry C ~ aA X (coefficient) 126 3(!TX) Tv, T,) 1 1 2 2 2 9 9 18 18 18 9 9 9 9 9 1 1 2 2 2 lfy = 126 = aJCAl + CAi + 2CEl + 2CEt + 2CEa}; therefore aA = V¥ = 9
158 Application and Special Gases The irreducible representation for these carbons and hydrogens is rCiH - 9A1 + 9A2 + 1SE± + 18E2 + 18£3 The total irreducible representation rtot = Toxy + Tc H: nAm 21Ef rtot = ptrans = A% + Et prot-ckain axis A The irreducible representation for the intramolecular vibration is pintramol vib ptot ptrans prot pintamolvib Type 3. General equations for helical molecules 1. For helices with symmetry isomorphic to Cn: n monomer units (containing p atoms) and m turns in helix. Here the factor groups are isomorphous to Cn—no atoms lie on helical axis, i.e., all local symmetry Cx; therefore/7 = 3n x p. For n odd the general irreducible representation can be written as follows: r Symmetry of monomer atoms C1 Factor group symmetry 3np 3G;, Tv, Tz) A 2 3p
Irreducible Representation for the KHF2 Crystal 159 Summarizing the total irreducible representation, we have rtot = 3pAn,m + 3^ir.k + 3pgR + 3pEo + ... and we write the irreducible representation for translation and rotation: ptrans = A + ^ ptot = A These are subtracted from rtot to give pintramolvib = ^ _ 2)A + Bp - 3pEz 3pEin_1)/2 For n odd r Symmetry of monomer atoms Ci Factor group symmetry 3np T T ) 1 V> 2 z) (n/2-1) 1 3p 1 3p 2 3p 2 3p 2 3d 2 3p Summarizing, we find ptot __ ptrans = A + Ei profc = A
160 Application and Special Gases Therefore the irreducible representation for the intramolecular vibration can be written in the general form intramolvib + ZpB + C/> + 3pE2 2. For helices with symmetry isomorphic to Dn with n monomer units, each containing p atoms and m turns in the helix; the factor groups are isomorphic to Dn. To derive the irreducible representation we assume that all atoms have Cx symmetry except those lying on C2 axes perpendicular to the helical axis. Let q = number of atoms lying on Ca axis per monomer unit; then p — q — number of atoms with Cx local symmetry. For n odd r Symmetry of monomer atoms Co Factor group symmetry = aA 2nq 2(Tx,Ty) B *= 1 q 1 2q 2 3q 2 3q 2 3q q 0 q q 0 2q 2q 2q n-D/2 2 Sq = q + 2q Therefore for q atoms per monomer unit lying on Ca axis Fo, = qA1 + 2qA2 + 3qE1 + 3?£2 + 3qE3
r Symmetry of monomer atoms ty Cx Factor group symmetry a^ = aA X coefficient S(Tx,Tv,Te) 1 2 2 2 HP-q) HP-q) 2 HP- 2 HP- HP- q) q) = q)- 2 3(p- 2 3(p- 2 3(p- 2 3(p- ■q) q) ■q) q) x 1 X 1 X 2 x 2 X 2
162 Application and Special Gases Next, for atoms on general sites Cl9 f = Sn(p -})=4i[lxl + lxl + (S^)B X HP-q) a a — 2 For atoms in Cx sites the irreducible representation is (A, + A2) + 3(p - q)[Ex + E2+E3 2 Therefore total irreducible representation can be written rtot _PP-9\A , CP + 9\A + 3pE3 + • • * + 3pE(jl_1)/2 ■ptrans a \ f? prot helix axis a •pintramol vib Cp - l)Eln'R + 3pEf +--' +3pE°n_1)/2 For n even there is no general formulation that will apply to all the Dn groups, and each case must be worked out as in Type 2 already described. Type 4. Layer structures. Here we use graphite as our example. X-ray data: Clv(P§zmc), Z = 4. The carbon atoms are on
Irreducible Representation for the KHF2 Crystal 163 Sites a and b 1. First the isolated sheet or layer is considered. (This is analogous to the line group considerations in linear chains.) Sheet symmetry: D6h Symmetry of carbon atoms in sheet: DZh Correlation: DZh —y-> D6h C2 There are two carbon atoms in P f 4 2G;, 2 \(TZ) ptot 1 sheet p trans x sheet pintramol sheet Carbon atoms site symmetries r-n \ rpf _ Tv) E ^- ^- All = B2g + A2u + E2g ptot ptrans sheet sheet the repeat unit Symmetry of layer r °* + Elu K + K per 1 = 1 = 1 = 1 = sheet: ' aE' + ■- 1 + = 1 + = o + = 0 + It 0 0 1 1 There are no librations of an infinite sheet. Tuinstra and Koenig* observed one Raman scattering frequency and no infrared absorption. These observations are consistent with selection rules predicted for a layer. 2. If there is interaction between layers in graphite, the selection rules would be derived as follows: the sheet symmetry DQJl is correlated to the site symmetry of the layer CZv which in turn is correlated to the factor group symmetry C6v. The degrees * F. Tuinstra and J. L. Koenig, J. Chem. Phys. 53, 1126 A970).
164 Application and Special Cases of freedom/7 = (number of sheets = 2) X (Cy, the degeneracy of each species of the sheet symmetry Deh). r o 4 2 4 Sheet symmetry 2 - ^ <j At1 Layer site symmetry — A ^^-^ Factor group ->• symmetry E1 a( o 2 2 2 Therefore the total irreducible representation is ■ptrans a \ T? space group 1 ' 1 There are no rotations. The irreducible representations of this layered structure is ■pintramol "ntot "ptrans ATR,~R \ odO _i_ i^IR.R i orR space group 1 "• "^ 1 ' 1 ' ^^2 The above representation for intramolecular vibrations predicts two infrared active vibrations and four Raman active frequencies. As previously noted from Koenig's work, there was only one Raman frequency observed; therefore it must be concluded that there is weak interaction between the layers and no coupling of vibrational modes. Example 6. Selection rules for some common inorganic structures. The following information is readily available in the literature. The irreducible representation and selection rules are the same for all inorganic crystals that contain the same crystallographic structure. These examples are presented to
Irreducible Representation for the KHF2 Crystal 165 allow the reader to test his ability to apply the practical rules presented here and/or to save him some time if the selection rules are needed for certain types of inorganic structure. aragonite strugture. Representative example CaCO3. X- ray data D\l-Pnma (Space Group 62), ZB = 4. Number of atoms in eq. site 4 4 4 8 T Atom Ca C Oxy Oxy Wyckoff site c c c d Af + 6< + O DR I Q pH - OX>30 -f- OJJlu Schonflies notation for site c, Cs cs 9Bfa 1 + 5Bl* + 8 Correlation azx Gzx inactive p. A rutile strugture. Representative example TiO2. X-ray data K-Pi2/mnm (Space Group 136), ZB = 2. Number of atoms in eq. site 2 4 active F inactive Atom Ti Oxy = Afg - = A2g - WyckofF site a f r -Dig ~r -E>2g "T i O Z? Schonflies notation for site c2v -Ef+Al«- Correlation r" acoust — -^2m i ■"«
166 Application and Special Cases anatase structure. Representative example TiO2. X-ray data D^I,1/amd (Space Group 141), ZB = 2. Number of atoms in eq. site Atom Schonflies Wyckoff notation site for site Correlation 2 4 Ti Ox a e c'i active 3E ■R 2Eln inactive J2u p A x acoust ~ ^2 ilmenite structure. Representative example FeTiO3. X-ray- data Cti-Rs (Space Group 148), ZB = 2. Number of atoms in eq. site 2 2 6 Atom Fe Ti Ox Wyckoff site c c f Schonflies notation for site ca c3 = 5A* + 5Ef + AA™ + acoust
Irreducible Representation for the KHF2 Crystal 167 calcite structure. Representative example CaCO3. X-ray data Dla-Rzc (Space Group 167), ZB - 2. Number of atoms in eq. site 2 2 6 Atom Ca C Oxy Wyckoff site b a e Schonfiies notation for site s* c. rinactive "P A i J? acoust ""-Zu T* J-Ju wurtzite structure. Representative example ZnS. X-ray data Civ-PQMeIm (Space Group 186), ZB = 2. Number of Schonfiies atoms in WyckofF notation eq. site Atom site for site Correlation 2 Zn b C3v ov 2 S b C, a,, -p jR.IR , t?R,1 1 active = Al + ^1 " inactive ^13 acoust 1 "•" 1
168 Application and Special Gases pyrite structure. Representative example FeS2. X-ray data T%-Pa3 (Space Group 205), ZB = 4. Number of Schonflies atoms in Wyckoff notation eq. site Atom site for site 4 Fe b S% 8 S c C, ^active = Ag + Eg + 3Fg inactive ^-^-u "i ^-^u F = F acoust u zing blende structure. Representative example ZnS. X-ray data 7t-Frsm (Space Group 216), ZB = 1. Number of Schonflies atoms in Wyckoff notation eq. site Atom site for site 1 Zn a Td 1 S b Ta p active
Irreducible Representation for the KHF2 Crystal 169 fluorite structure. Representative example CaF2. X-ray data Ol-FmZm (Space Group 225), ZB = 1. Number of Schonflies atoms in Wyckoff notation eq. site Atom site for site 1 Ca b 0h 2 F c Ta r active t-TR r = f, acoust lw* spinel structure. Representative example Al2MgO4. X-ray data Ol-FdZm (Space Group 227), ZB - 2. Number of Schonflies atoms in Wyckoff notation eq. site Atom site for site 4 Al d DM 2 Mg a Td 8 Oxy e CZv ^active = Fl9 + 2^2M + 2£u + 2F2u, r — f acoust lw
REFERENCES 1. D. F. Hornig, J. Chem. Phys. 16, 1063 A948). 2. H. Winston and R. S. Halford, J. Chem. Phys. 17, 607 A949). 3. S. Bhagavantam and T. Venkatarayudu, Theory of Groups and Its Application to Physical Problems, Bangalore Press, Bangalore City, India, 2nded., 1951. 4. Charles Kittel, Introduction to Solid State Physics, Wiley, New York, 4th ed. 5. John C. Slater, Quantum Theory of Molecules and Solids, McGraw-Hill, New York, Vols. I, II, and III. 6. J. R. Durig and D. J. Antion, J. Chem. Phys. 51, 3639 A969). 7. International Tables for X-Ray Crystallography, Vol. 1, N. F. M. Henry and K. Lonsdale, Eds., 1965, Kynoch, Birmingham, England, 2nd ed. 8. R. W. C. Wyckoff, Crystal Structures, Wiley-Interscience, New York, Vols. I and II. 1964. 9. R. K. Khanna and C. W. Reimann, A Simplified Method for Symmetry Classification of Vibrational Modes of Molecules {Correlation Method), Spectra- Physics Raman Tech. Bull., No. 3, 1970, Spectra-Physics, 1250 West Middlefield Road, Mountain View, Calif. 94040. 10. David M. Adams, Metal-Ligand and Related Vibrations, St. Martin's, New York, 1968. 11. E. Bright Wilson, Jr., J. C. Decius, and Paul C. Cross, Molecular Vibrations, McGraw-Hill, New York, 1955. 12. G. Herzberg, Molecular Spectra and Molecular Structure. Vol. II. Infrared and Raman Spectra of Polyatomic Molecules, Van Nostrand, Princeton, N.J., 1945. 170
APPENDIX I SITE SYMMETRY TABLE FOR THE BRAVAIS SPACE CELL The following table was compiled from the site symmetry tables for crystallographic groups found in the International Tables for X-ray Crystallography, Vol. I. Please note that the table is modified and should be used only for the Bravais space cell and the Halford site symmetry correlation method suggested in this book. The site symmetries are arranged in alphabetical order, reading from left to right. We refer the reader to Chapter 2 (p. 36) for an explanation of this ordering. Note also that no coefficient precedes the general site Cx because an infinite number of these sites are present. 171
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 Space group PI PI P2 P2, B2 or C2 Pm Pb or Pc Bm or Cm Bb or Cc P2\m P2,\m B2\m or C2jm P2\b or P2\c P2,jb or P2Jc B2jb or C2\c P222 P222X P21212 P212121 C222X C222 F222 1222 12,2,2, Pmm2 Pmc2, Pcc2 Pma2 Pca2, Pnc2 Pmn2, Pba2 Pna2, Pnn2 Cmm2 C1 C1 cl to to cl c1 cl cl c4 L2h c\n ck CL CL CL D\ D\ Dl D2 D\ D\ D\ D\ Dl clv c\v clv c\v ctv c1 clv Clv Clv ell Site symmetries Ci(l) 80,AM^B) 4C2A);C1B) CiB) 20,A); 0^2) 2CSA);C1B) CiB) 0,AM^B) CiB) 8O2ft(l);4C2B); 20,BM 0^4) 40,B); C,B); CxD) 4Cu(l); 20,B); 2C2B); 0,B); CxD) 40,B); 20,BM 0^4) 40,BM 0,D) 40,BM 0,BM 0,D) *-)jt-^2\ / ' ^ 2\ ) 9 1\ / 40,BM 0,D) 20,BM 0,D) 0,D) 20,B); 0,D) 4ZJA);7C2B);C,D) 4Z),A);6C2B);O1D) 4D,AM 60,B); 0,D) 30,B); 0,D) 4Cgv(l); 4OsB); 0,D) 20,BM 0^4) 40,B); 0,D) 2C2B);CSB);C,D) C,D) 2C2B);O,D) 0,BM 0^4) 20,B); 0,D) C,D) 2C2B);C,D) 20^AM 0,B); 2CSB); 0,D) 172
Space group 36 Cmc21 37 Ccc2 38 Amm2 39 Abm2 40 Ama2 41 Aba! 42 Fmm2 43 7ta/2 44 7mm2 45 Iba2 46 7ma2 47 Pmmm 48 Pww 49 Pcctyi 50 Pte 51 Pmma 52 Ptttttf 53 Pmwfl 54 p££# 55 Pbam 56 Paw 57 Pbcm 58 Pmzm 59 Pmmw 60 Pbcn 61 Pfoa 62 Pnma Do dmcm 64 Cmc<z 65 Cmmm 66 Cccm 67 Cmma 68 Ccftz C12 C2tf C14 cj; c17 c^ cJJ c20 c21 c|2 dJa Dth D2h D\h 7M U2h Dth Dlh Dlh Dlh DH D11 2I2 2fi 7~\14 7I6 JJ2h 2I7 7I8 D2h 7J0 1J2h DH 2J2 Site symmetries 0,BM 0,D) 30,BM 0,D) 2CMA);3C,B);C1D) 202BM 0,BM 0,D) 0,BM 0,BM 0,D) C2B);C,D) C2,A);C2B); 20,BM 0,D) C2B);C,D) 2C2,A); 20,B); 0,D) 2O2B);O,D) C2B); 0,B); 0,D) 8D2h(l); 12C21,B); 60,D); 0,(8) 4ZJB);2C,D);6C2D);C,(8) 4C2ftB); 4Z>2B); 8C2D); 0,D); 0,(8) 4^BM 20,DM 60,DM 0,(8) 4C2AB); 2C2,B); 2C2D); 30,D); 0,(8) 20,D); 20,D); 0,(8) 40^BM 30,DM 0,DM 0,(8) 20,D); 30,D); 0,(8) 4O,ftB);2C2D);2C,D);C,(8) 2C,D);2C2D);C,(8) 20,D); C2D); 0,D); 0,(8) 4C2ftB);2O2D);C,D);C,(8) 2O2sB); 20,D); 2CSD); 0,(8) 20,D); C2D); 0,(8) 20,D); 0,(8) 20,D); 0,D); 0,(8) 2C2ftB); C2VB); 0,D); C2D); 20,D); 0,(8) 2C2AB); 0,D); 2C2D); 0,D); 0,(8) 4D2h(l); 2C2ftB); 6C,,B); 0,D); 4C5D); 20,B); 4O2,B); 5C2D); 0,D); 0,(8) 20,B); 4C2ftB); C,,B); 5C2D); 20,D); 20,B); 20,D); 4C2D); 0,(8) 173
Space group 69 Fmmm 70 Fddd 71 Immm 72 Ibam 73 Ibca 74 Imma 75 P4 76 P4X 77P42 78P43 79 74 80 74X 81 P4 82 74 83 P4/m 84 P42/m 85 P4/n 86 P4Jn 87 74/m 88 74^ 89 P422 90 P42X2 91 P4X22 92 P41212 93 P4222 94 P422X2 95 P4322 96 P432X2 97 7422 98 74X22 99 P4mm 100 PUm 101 P42cm D23 7J4 Dll 2J6 D21 D28 C\ ct cl ct cl s\ s2 c1 c2 c3 cth cl D\ D\ D\ d\ Dl D\ Dl Dl Dl D™ Clv C2 C3 Site symmetries 2D2AA); 3C,,B); D2B); 3C,,B); 3C2D); 2^BM 20,DM 30,DM 0,(8) 4ZJft(l); 6^,B); 0,D); 3CSD); 0,(8) 2Z»2B); 2CaB); 0,D); 40,D); CsD); 0,(8) 20,DM 30,DM 0,(8) 2C4A); 0,B); 0,D) 0,D) 30,B); 0,D) 0,D) O4A);C2B);C,D) O2B);C,D) «4A); 30,B); 0,D) 4S4A);2C2B);C,D) 4C4ft(l); 2C,AB); 2C4B); 0,D); 2CSD); 0,(8) 4O»B) 5 254B); 30,D); CSD); 0,(8) 2S4B) ;C4B); 20,D); C2D); 0,(8). 2O*(l); C2ftB); 54B); C4B); 0,D); 0,D); 254B);2OD);OD);O(8) 4D4A); 2D,B); 2O4B); 70,D); 0,(8) 2D,B);C4B);3OD);O(8) 30,D); 0,(8) 0,D); 0,(8) 6Z>,B); 90D); 0(8) 2Z),B); 40,D); 0,(8) IC (A.\ • C* SR\ OL/2^ttJ , Uj^Oj 0D); 0(8) 2Z>4A); 2D2B); C4B); 5C2D); 0,(8) 2£),B);4O,D);C,(8) 2C4r(l); C2v{2); 3OsD); 0,(8) OB); 0.B) ;OD); 0(8) 2C,,B);C,D);CSD);C,(8) 174
Space group 102 P42nm 103 P4cc 104 P4nc 105 P42mc 106 P4zbc 107 /4mm 108 I4cm 109 I\md 110 I\cd 111 P42m 112 P42* 113 P42xm 114 P42xc 115 P4m2 116 P4*2 117 PU2 118 P4n2 119 74m2 120 I4c2 121 /42m 122 Il2d 123 P4\mmm 124 P4\mcc 125 P4\nbm 126 P4\nnc 127 P4/m6m 1 O Q DA 1 ~,~ I/O LiT\V(lYlC 129 P4/nmm Ctv Clv Ctv Clv clv Clv 4v Cll Clv D\d Dtd Dld D\d D\d Dtd Dld Dld K D\\ D\l D\h D\h D\h DU DL Dk Din Site symmetries C2eB);C2D);CsD);C1(8) 2C4B);C2D);C1(8) C4B);QD);C1(8) 3(^B); 2CtD);C1(8) 2C2D); ^(8) CivW;C2vB); 2CSD);C1(8) C4B);C2KB);CSD);C1(8) ^BM^DM^(8) C2D);q(8) 4D2d{\); 2Z>2B); 2C2BB); 5C2D); CsD); q(8) 423,B); 254B);7C,D);C1(8) 2J4B);CtoB);C,D);C,D);Cl(8) 254B); 2C2D); q(8) 4Z)MA); 3C2sB); 2C2D); 2CSD); ^(8) 223,B);2J4B);5C,D);C1(8) 254B); 2ZJB); 4^DM^(8) 2J4B); 223,B); 4C,D); ^(8) 423MA); 2CtoB); 2C2D); C,D); q(8) n /'9^ • 9 c /'9^ • d fo\ • 4./° (&\ • r* ^^ X/2\^'// j ^^4\^/ 5 -^2\ / > ^^2v^/ s ^iv. / 223^A); 23,B); J4B); C2sB); 3C2D); C,D); Cx(8) 2S4B);2C,D);Cl(8) 423tt(l); 2D2AB); 2C4rB); 7C2,,D); 5CS(8); 234B); C4AB); 234B); C4ftB); C2ftD); 23,D); 2C4D);4C,(8);C,(8);C1A6) 2£>4B); 2D2dB); 2C2ftD); C4D); Civ{4); 4C2(8);CS(8);C1A6) 2Z>4B); 23,D); 54D); C4D); Q(8); 4C2(8); 2C4ftB); 2Z32ftB); C4D); 3C2l)D); 3CS(8); 2C4ftB); C2hD); 23,D); C4D); 2C2(8); Cf(8); 2232dB); C4,B); 2C2AD); C2,D); 2C2(8); 2C,(8);C1A6) 175
Space group 130 P4\ncc loi fr2f nitric 132 P42jmcm 133 P42\nbc 134 P42\nnm 135 P42/mfo 136 P42jmnm 137 P42jnmc 138 P42\ncm 139 /4/wmm 140 /4/mcm 141 ^/^m^ 142 J^/aci 143 P3 144 P3X 145 P32 146 R3 147 P3 148 R3 149 P312 150 P321 151 P3X12 152 P3X21 153 P3212 154 P3221 155 £32 156 P3m/ 157 P31m Din D\h D\l D\l D\l D\l Djk D\l D\l D\l D\l C1 r2 °3 cl ch ch #*. D\ D\ D% D\ D% Dl ch cl Site symmetries 0,D); J4D); C4D); C,(8); 2C2(8); CxA6) 402ftB); 202dB); 7C21)D); 0,(8); 3CS(8); ^2/,B); 02<*B); 02ftB); 0MB); 0,D); C2ftD): 40^D); 30,(8); 2C,(8); ^A6) 302D); 54D); Q(8); 5C2(8); G,A6) 2DMB); 202D); 2C27lD); CtoD); 5C2(8); C»D); 54D); C2ftD); 0,D); 3C2(8); 0,(8); 20,»B); C,hD); J4D); 3C2,D); 0,(8); 2CS(8); 20MB); 2C2,D); 0,(8); 0,(8); 0,(8); C,A6) 02D); 54D); 2C2ftD); C29D); 3C2(8); 0,(8); C,A6) 204ft(l); 02ftB); 02dB); CivB); C2ftD); 4C2,,D);C2(8);3CS(8);C,A6) 04B); 0MB); C4AB); 0ttB); 0^D); C4D); 2C2eD);2C2(8);2Cs(8);C,A6) 202dB); 2C2ftD); C*D); 2C2(8); 0,(8); C,A6) >S4D); 02D); 0,(8); 3C2(8); 0,A6) 30,A); 0^3) 0,C) 0,C) 0,A); 0^3) 2C,,A); 20,B); 20,C); qF) 2C,,A); 0,B); 20,C); CiF) 603A);3C3B);2C2C);C,F) 203A);2C3B);2C2C);C,F) 2C2C);C,F) 20,CM 0,F) 20,C); 0,F) 203A);C3B);2C2C);C,F) 3C3,A);CSC);C,F) Cw(l); 0,B); 0,C); ^F) 176
Space group 158 P3cl 159 P3\c 160 R3m 161 R3c 162 P31m 163 P3\c 164 P3ml 165 P3d 166 R3m 167 R3c 168 P6 169 P6X 170 P65 171 P62 172 P64 173 P63 174 P6 175 P6/?n 176 P63/m 177 P622 178 P6X22 179 P6522 180 P6222 181 P6422 182 P6322 183 P6mm 184 P6<* 185 P6scm 186 P6zmc 187 P6m2 cl civ Czv cl D\d Bid DL DU Did ci ci ci ci ci ci C\h ch Dl Dl Dl Di Dl Dt Civ C2 c3 civ D\n Site symmetries 3C,B);C1F) 20,B); CxF) CSv(l); CsC); (^F) 03BM^F) 2D3d(l); 2D3B); C3v{2); 2C2ftC); C,D); 2C2F);CSF) 5^A2) D3{2); C3{B); 2D3B); 2C3D); QF); C2F); 2I>MA); 2C3SB); 2C2ftC); 2C2F); C,F); D3B); C3iB); 2C3D); C<F); C2F); CxA2) 2ZKd(l); C3v(z); /C2^(j); 2C2F); Cs(o); ^(Iz) JJo[Z): Oq,-(z); Cq(^); t/,-(o): C9(b); C-,(lz) Ci(l);C8B);C8C);C1F) CxF) C,F) 2C2C); CxF) 2C,C);C1F) 20,BM^F) 6C3AA);3C3B);2CSC);C1F) 2C6ft(l); 2C3AB); C6B); 2C2ftC); 0,D); C3ftB); CMB); 2C3ftB); 2C3D); 0,F); 0.F); 22>,A); 2D3B); 0,B); 2Z),C); 0,D); 5C2F); 20,FM ^A2) 20,F); 0^12) 42JC);6C2F);C1A2) 4i),C);6C,F); 0^12) 4ZKB);2C3D);2C2F);C1A2) 0e«,(l); C3^B); C2^C); 2CSF); CXA2) C6B);C8D);C2F) 5 0^12) C«.B); 0,D); 0,F); ^A2) 208,BM 0,F); ^A2) 65^A); 3C,,B); 2C,,C); 30,F); 0^12) 177
Space group 188 P6c2 189 P62m 190 P62<: 191 P^jmrnm 192 P6/W 193 P6Jmcm 194 P6Jmmc 195 P23 196 F23 197 723 198 P2X3 199 72X3 200 Pm3 201 Pn3 202 Fm3 203 Fd3 204 7m3 205 Pa3 206 7*3 207 P432 208 P4232 209 F432 210 F\32 211 7432 212 P4332 213 P4X32 Din Din Din Din Din Din Din T1 T2 T3 r4 T5 rpl rp2 n n n rpl o1 o2 o3 o4 o5 o6 o7 Site symmetries 0,B); C3AB); 0,B); C3AB); 0,B); C3AB); 3C3D);C2F);CSF); C,A2) 22>3AA); 2C3AB); O3J)B); 2O2t)C); C,D); 3CSF);C,A2) 0,B); 3C3AB); 2C3D); O2F); C,F); C,A2) 20tt(l); 22KAB); C6t>B); 22JAC); C3l)D); 5C2eF);4CsA2);C,B4) 0,B); C6AB); 0,D); C3AD); C6D); 0,F); C2ft(o); C3(o); JC2(lz); Cs(l/); Lx\l<±) 2KAB); 0MB); C»D); 0,D); C6D); C2ftF); C2,F); C,(8); C,A2); 2CtA2); C,B4) 0MB); 32)^B); 2C3rD); C2AF); CivF); C2A2); 2C,A2) 5^B4) 2 T(l); 202C); C3D); 4C2F); C,A2) 47-(l); C3D);2C2F); 0,A2) C3D); 0,A2) O3D);C2F);O,A2) 2rA(l); 20»C); 4(^,F); C,(8); 2CtA2); TB); 2C8iD); 0,F); 0,(8); 20,A2); 0,B4) 27\A); T{2); C2AF); C2eF); 0,(8); 0,A2); 2 T{2); 2C8ID); C8(8); 0,A2); 0,B4) 0,B4) 2C3l.D);C3(8);C,B4) 2C3iD);C3(8);C2A2); 0,B4) 20A); 204C); 2C4F); C3(8); 30,A2); 0,B4) . T{2); 208D); 302F); 0,(8); 5C2A2); 0,B4) 20A); rB);2JF);C4F);C3(8);3C2A2); 2 T{2); 20,D); 0,(8); 20,A2); 0,B4) 0A); 04C); 0,D); 0,F); C4F); 0,(8); 20,D); 03(8M 02A2M 0,B4) 22KD);C3(8);C2( 12); 0,B4) 178
Space group Site symmetries 08 20,D);20,F); 0,(8) 5 30,A2); CxB4) 7* 27^A); 20MC); CwD); 2C2,,F); 0,A2M 0.A2) 5 0^24) 7* 4rd(l); C3))D); 2C,,F); CsA2); CxB4) T* 7^A); 0MC); CwD); J4F); C*F); C2A2); CSA2);CXB4) T* T{2); 0,F); 2S4F); C,(8); 3C2A2); qB4) 7* 2 TB); 2^4F); C,(8); 2C2A2); qB4) 7* 25,F); C,(8); C2A2); CxB4) Oj 20A(l); 2D4ftC); 2C4,F); C3r(8); 3^,A2); 3^B4M^D8) O\ 0B); D4F); Cw(8)j J4A2); C4A2); C,A6); 2^B4M^D8) 0* 7^B); D2hF); 2D2dF); D3(8); 3C2,A2); C3A6);C2B4) 5 0,B4M^D8) 0* Td{2); 2Z>3dD); D2dF); C3,(8); 0,A2) 5 C2sA2);3C2B4);CsB4);C1D8) 0\ 20»(l); TdB); DuF); C4l)F); C3v(8); 30^,A2M 20,B4M 0^48) 0« 0B); 7\B); D2dF); C4ftF); CtoA2); C4A2); 0,A6M 0,B4M C,B4); ^D8) 0\ 2 TdB); 2£>3dD) 5 0^(8); C2v{\2); CsB4); 0,B4M 0^48) Oj TD); 0,(8); CM(8); J4A2); 0,A6); 2C2B4); 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 /4X32 P43m F43m /43m P43n F43c I43d Pm3m Pn3n Pm3n Pn3m Fm3m Fm3c Fd3m Fd3c Im3m Ia3d 0\ 0h{\); 0ttC); D3dD); 0MF); 0^F); C3v(8); 2C2^A2); C2B4); 2CSB4); 0^D8) Of C8i(8M 0,(8); 0,A2M 54A2); 0,A6M 20,B4M 0^48) Note the following equivalent nomenclatures: dI - vd 179
APPENDIX II CHARACTER TABLES The symmetry operations present in each point group are described in References 3, 11, and 12. The species of the translations Txy Tyy and Tz in the x,j, and z directions, respectively, and the rotations Rx, Ry, and Rz in a right-handed system parallel to the x, y and z axes, respectively, are given for each point group. Also, the species of the polarization tensor elements, a#, is identified for each point group. This allows us to determine immediately the spectral activity of each species in a point group; for example, all those species that contain a translation will be infrared active, whereas those species containing an element of the polarization tensor oc# will have Raman activity. The combination levels v{ + vh difference tones, vt — vjy and overtone levels Bvi9 2vjy etc.) symmetry can be determined by using these tables. A description of this procedure is given in Wilson, Decius and Cross, [11], especially Chapter 7. 181
A' A" 1 1 1 -1 Rx, Ry A A E 1 1 i 1 -1 Ry, T } Rz axx, a,w, a2Z, *„, «.xz, xyz c2 A B E 1 1 Cm 1 I 35 ^055 "* y I R, ■ ■Kx> ^y *xx> *yy> *zz> *xy &*XZ) &yz c*h Ag Bg Au Bu E 1 1 1 1 c2 1 -1 1 -1 i 1 1 -1 -1 °* 1 -1 -1 1 Rz Tz Tx,Ty a«*» *yy> «-zz> *xy <*-xz> Kyz c2v A A B2 E 1 1 1 1 c2 1 1 -1 -1 av(zx) 1 — 1 1 -1 1 -1 -1 1 Tz Tx; Ry Ty;Rx a**5 «w> *zz a*2 OLyz A Bx B2 Bz E 1 1 1 1 CmW 1 1 -1 -1 Cm&) 1 -1 1 —1 1 -1 — 1 1 1 z>Kz Ty, Ry TX,RX OLxy <xxz *yz 182
to* <M ^H -H ^H ^ O _H »-H r-X ^ CN I — -H rt -. O r—« r-H f—i r—J O*I If n a 8 ftj a^ ct; 1 1 1 I 1 1 1 1 1 1 1 1 1 1 1 1 E-rE-Tf-,8 1 1 1 ! 1 1 1 1 1 1 1 1 8 ■ft- o. a a 183
184
E-H £ ft! CO r-< -< O -H ^H O ^ r-4 O —I ^ O I I I ^ ^ CM i-< ^ CM I I I ^ *-< O ^H r-H O I CM I CM ^h _., CM *-* —i CM -H -H O -^ —* r^ r-H CM —< —• CM «—t 'to ««^ 185
8 « „ 8 8 OS h a 8 III I T 7 7 7 i - i i | - rt " " 7 7 7 7 I I '- II- CM I I ^-H 1 1 O I I cf 3 r-l <M cq cq 186
CM CM CJ II CM H 8 ^77 _ _ ,-H 1 r_H i 1 r—J ^H ^H ^ — -H -* W (N r-i ftf ^ o 1 -h CM 1 ^ o 1 r-< CM CO 00 CM CM ftf r-H ^H r-H ^H O O O I I r—t i—I r—I r—( O O O _< _h ^ CM CM CM I I *-h —« —• I CM O I CM -H -H —< r-l O CM O —I -H r-i | CM O I CM *-H r-H CM CM CM 187
b (M 8 1 8 ** I I CM r-H r-H ^H r-^ CM I I I I ll M H H CM r 7 7 71 ■f- I 8 8 51 7T o CM I I I f—< r—\ ~-< CM i—• »-h I I • I I I I fel rH <M t-I t-(<Mt-H<M 188
* CO CO CO CO CO CO CO CO * 04 CO CO CO * ©4 ©4 * CO CO CO CO r-< CO CO 04 04 * 04 04 CO CO CO CO r-H CO CO 04 04 * ©4 ©4 CO CO CO CO ,—i CO CO I I I ©4 04 r-H CO CO I I I 04 ^H CO I I 04 CO I CO * 0* 0* # CO CO CO CO ,-h CO CO I I I I I CO I 4 ©4 CO CO Mil! CO 04 CO CO 04 CO * ©4 CO CO * CO ^H CO * ©4 CO CO ©4 CO •* ©4 CO CO 04 CO * CO 04 ©4 * ©4 ©4 CO CO CO CO i—1 CO CO w eJ ©4 ^ ©4 ©4 i—«COC0C0C0r-HC0COC0CO 189
t? m 0310 CJ CM O CM 8 8 1 T" £ 8 - —• T-H T-H rH s—< 8 51 ftj ^ 1 O ^ 8 0 CM 0 CM CM »-h CM 8 » 9> 8 | 1 H O O CM 8 O CM 0 cos ] CM CM IS CM o CM Ci ^ 8 8 ' ft! ^8 0 O CM CM CM ^f r>^ t-h CJ CJ CM CM r-H t-H CM CM OS — -h O O cm CM m 8 8S 1 «* •—lr-HOO»-Hi-HOO CM 8 8 7 CJ O I CM CM r-H CO O CJ CM 1 0 CM $>. Q CJ CM I CO 0 CM CM 8 T CJ I CM CM -h 1 1 8 1 CJ CM 1 r-H CM 1 1 8 CJ CM 1 CM i r-H-^OO'-H'—<OO CO CO o o CJ O CM CM CM o o CJ CJ CM CM 0 CJ CM —H CM 8 CM CM r-H O CJ CM r-H CM 8 CM CM fcs 190
to eo 8 8 CM CM i-^ <^> f^> t** CM CO CO 8 8 cm csr i i §77 CM CM o ^t1 CM ^ CO CO O O CJ O CM CM I I r-H r—I CM CM <""""• r"H r-.r-.OO CM CM I I o o CJ O CM CM O O CJ CJ CM CM "tf« CM CO CO CJ CJ CM CM 5 CO CO CJ CJ CM CM ft! ft? r—, r-H CO CO * r-H CO CO * CO CO CO CO I I I I CO CO t-H CO CO # CO CO CO CO hh^(NhhM(N hi 191
I * t + J I «T of oo 111 I 1 I I I 1 I I I 1 1 1 CO * co CO 1 I * co * CO CO * CO 1 1 CO * co 1 co 1 * co 1 CO CO »—c 1 1 1 CO —t 1 CO r-1 1 * CO »—f i—I CO 1 1 1 * r-H CO 1 —1 CO 1 1 I »—i CO # CO 1 1 CO CO 1 1 CO * co 1 CO 1 * CO 1 CO CO 1 •3f CO 1 CO 1 CO MM I I I I I I I v^3 CO CO o csr + , , , 1 , 1 1 r-< ^ r-H I 1 r-H r-H r-H 1 « _ _ iH N iH it * 1 -h O O r-< O O 1 7c vT (M I i i «-* CSf CN 192
ftf !-H T-H O O ,-H r-H t—H . 1 O O I I I I I ~ ~ 7 7 "" 7 M rt ^ M (M (M afaf bfi CD CM Cj CM CM CM CM Si — — -< '-. O 1 1 i-H »-H t-H «-> 1 H O ^H r-< r-H r-H CM I " " 7" 1 i ^ ^ _ _ o 1 hhhh|M 1 1 > _ ^H ^H _ CJ <^"af ft ! o o CM CM 1 1 r-H CM O o CM o 1 o CM o o CM 7 i CM 1 7 CM j o o CM 1 > 1 o 1 CM 193
to9 CO <? eo CN <>? cn CO b1 CO CN o CN rt77"oo7'"rt' -O© rt«rt^HO©'-<-H—"—'O© 1 < 1 1 H (M (N -< -H ^ H (N C III 1 1 1 1 1 1 M I | ~~~H~°'<N77" " 7" H r- H r- -i C sr c ^©O H ° ° " 7 rt"" , Cj, <^ „ _ .- 1 i H r— -• o o 1 CM 1 1 I N<N ^^ _- * S „« Ji ^ ^ ^ q| a- ^ [| II 11 CO to ■a? CO ^7 1 8 H •X- r-H CO CO r—1 CO CO * r-H CO CO •X- r-H CO CO to CD * r—1 CO 1 1 r-H CO 1 1 1 1 * r-H CO r-H CO CO 1 * CO 1 1 CO CO 194
af 7 w w 7 "* T T III! * eo to .« .« II! I * ri eo to co co r-i CO CO .^ I I I I CO CO 7 7 7 7 r—I CO CO .^ .«> CO CO I III to8 8 * CM ft ^ 8 r-H ^H O 1 . in *"• —■* o o CM r-« r-l CM w w e 111 ill II! Ill III 111 iH <M tH 1 i o CM in o O CM CM III III ■4" o • • CO 6/5 * o * CM CM • e : 111 • III CO oq <N CO 195
t,8 CM 8 8* CM CM I ^"H r-H (M CM O O 8 8 CM CM —< *-* CM CM r—I r-H (^) ^) -$-CM  o o | u o CM CM CM r~. r-H O O -©-CM CO CO o o O O CM CM -H r-H Of CM CO 8 ^ ^ ^ CO CO O r-H CO CO O r-1 r-H r-H CO 196
to 3 oo « CM * to" co ,-H _ O —« -H --O-- 5 »-H i-H CM •"-"« l~~< _H ^H ^ O O CO 01 CO CM CO CO ^ 8 « « CM + I " rt 7 7 7 7"" co to o h co co o I I I co co o *—« W co o I I I I I I """ 7 " " " 7 co co o »—« *$ co o 197
t£> CO co _4 O —< r~1 I I _H © "-* »-H I I t-H CM *—• »~H' ^ _< _< o O »-H r-H CM CO CO to" CO 0 CO co o co CO CO —< —( O I f—It—I CM o III I I I I I f-H Q> <3 ,-4 _I r-H O O I I I (N COCO-H-HCMCOCO I I I I I I I II I I CO CO rH rH (N CO CO 198
CM I i I I -H O O —< -H CM Im ■? ■s CM r-i O -H O -h CO CO ^ if) 199
of CM I m III I ~* —i O O O O y* —< i-h 1 I M rH ^ O O 3 I CM -h ^ O O «~( —i co I I I I ! I I —< —• O O O o-h,-*^.-. 1 in ^ > '-I CM im CM > CM , —i -* O O I I CM + CM CM 1 —« .-I © © CO CO CO CO ft? b? O^clttT^ 200
APPENDIX III CORRELATION TABLES We have not attempted to list all possible correlations between the different point groups; for example, if the correlation between D^ and 0h is desired, it can be carried out in two or, if necessary, more steps. First we would write the correlation from Dooh to ZLA; then the correlations that relates from ZL7t to 0h would give the desired relationship between D aoh and 0h, The reader can also construct the correlation tables (see Chapter 2 for details) from the character tables given in Appendix II or from the group theory of the individual point groups. Since the correlations depend on certain choices in axes, planes, or both, this choice is identified above each subgroup of a point group. This information is of great importance in applying Table 14; for example, in the correlation table for 201
202 Appendix III C2v there are two columns relating the Cs subgroup. These are given as follows. (This portion identifies the plane in C2v which contains the equivalent set of atoms of site symmetry Cs. (See Chapter 2, p. 38, for an example.) A A, Bt B2 a(zx) cs A' A" A' A" o(yz cs A' A" A" A' Those species of the point groups C9h9 C^h, C5h, CQh, C6, £4, S6, S8, T, and Th marked with an asterisk (*) will not use the coefficient 2 of the Ei species in this correlation procedure only. Also, for those species of the point group 7* and Th marked with a double dagger (J) a coefficient 2 will be added to the E4 term related to the Ft species of the point group. Several examples, in particular 3 and 4, which illustrate this change, are given in Chapter 5. ^2h A, Bg Au Bu c, A B A B cs A' A" A" A' Ag A Au Au ^2v Ax A, B1 B2 c% A A B B a{zx) cs A' A" A' A" a(yz) cs A' A" A" A' A B1 B, Bz ci A A B B pV ^2 A B A B px ^2 A B B A A A2 B2 E c A A B B E . 2-+C2(z D2 A Bx A B\ ^2+B3 ) c2 p s~t ^2v ^2 A± A -A-2 -^i A A /In /I A A -ill jCX Did O Z? Jj-i-f-JDo ^13 C2 c2 A B A B A+B Cs A' A" A" A' A'+A"
a(zx) b o° o* cl ci <M •< 5; 5: « 5: «k ^« *** r-l <M <M iH Ol O> tH ©4 X! xj" xT Cd CO ft; CO xj 3 3 xj «r 3 (M 3 3 XJ X! «, xj ft; .,• (N ft; 3 Of xj x| 3 «r CO ft; CO ft; 203
A' Ef A" E" C* A E A E cs Ar 2A'* A" 2A"* Ci A 2 A* A 2A* Ax A2 E c3 A A E A' cs A' A" + A" ^3 A E Cs A A E A c2 A B + B D3d Alg A2g Eg Aiu eI Ax E Ax E c3v Ax A, E A2 Ax E Ag A Eg Au Au Eu ■ cz A A E A A E Cu Ag Bg Ag + Bg Au Au + B, A « A c2 A B + A B + B B A' A' cs A' A" + A" A" A' + A" ct AB Ag 2A, Au 2AU D3h A'x A'z E' A'i Al E" cSh A' A' E' A" A" E" D3 Ax A2 E Ax A, E c3v Ax A, E A2 Ax E Ax At > av{zy) c2v Ax B% + B% A, + Bx C3 A A E A A E A A c2 A B + A B + B B cs Ax A' 2A' A" A" 2A" A' A' ct A' A" + A" A' + A" A" A B E C, A A 2B C*n A* Bg Au Bu K A B E A B E s, A B E B A E C>2h A9 Ag 2B* Au Au 2B* c2 A A 2B* A A 2B* cs A' A' 2A"* A" A" 2A'* Q Ag Ag 2A* Au Au 2At Cx A A 2 A* A A 2A* * The coefficient 2 is not to be used in this correlation method; see p. 202 and Chapter 5, examples 3 and 4. 204
c A A2 Bx B2 E c* A A B B E C2v A A2 A Bx+Bz cl Ax A2 A B,+B2 c2 A A A A 2B C, A' A" A' A" A' + A" c. A' A" A" A' A' + A" At A, Bx Bz E c2 D2 A B1 A Bx B2 + B3 J c2 A Bi B1 A B2 + B c, A A B B c2 A A A A 2B c; c2 A B A B A + B c2 c2 A B B A A+B c2 Ax A2 B2 Ex E2 D, Ax A2 Ax A2 E ■#i +B2 E A A2 A2 E D 1 Z? 151 + ^2 E A A B B Ei E2 Ez c, A A A A E 2B E &2V Ax A2 A Bx + B2 Ax + A% Bx+B2 c2 A A A A 2B 2A 2B A A A c2 A B A B + B + B + B A' A' A' C$ A' A" A" A' + A" + A" + A" 205
J) Q - CO "A W <? <? b"<J «■«? ^^ ■^j cq cq "^ rH i-i ^^^05 ^^05 05 to to to rH r* to ■^j cq cq ^ to & & ^ oq1^ cq^ -:Vo5ao5s rH 03 rH (N rH Cd ©3 r- ^•ofaf S § 3 1 + | eo + eo + CO o? °q "a cq 3 3 IN of cq^cq cq ^ 3 S cq'cq' or^? 3 3 ^Bf tfvl r- ^ cq tj cq <=q 3 3 af «? of r- eo ©3 cq • ©\ cq cq1 rH 05 rH cq CO cq CO cq cq1 CO fiq b? CO «. * o"^ CM cq cq oq • cq ' cq cq ^ cq cq r«?«f- + 3 cq to_to , 3 cq ! cq ! oq ■ CM ^cq^ cq cq oq N rH ^j ^5 oq cq H4 206
A B E A A 2B* Ct A A 2 A* A' K E'2 A" E'i El ct A Ex E2 A Ex E2 cs A' 2A'* 2A'* A" 2A"* 2A"* Cx A 2 A* 2 A* A 2 A* 2A* Ax A2 Ex E, cs A A Ex E, A' A' cs A' A" + + A" A" Ax As Ex E2 Q A A Ex E2 A A ct A B + + B B Ax, Aig Ex, Eig ^2w Exu Eiu D5 Ax A2 Ex E2 Ax A2 Ex E2 Ax A, Ex E2 A* Ax Ex E, c5 A A Ex E, A A Ex E2 A A A A c2 A B + + A B + + B B B B A' A' A' A' cs A' A" + + A" A' + + A" A" A" A" Ct Ag AB 2Ag ZAg Au Au 2AU 2AU A'x A'z El E'2 A'i Al E'i El D, Ax A2 Ex E2 Ax e\ E, c» Ax A2 Ex E2 A2 Ax Ex E2 Af A E{ E2 A" A" E'i El A A E1 i E2 j A A E1 j E2 2 ->■ a(zx) c2v A Bx k + B2 h + &2 B2 12 + B2 A A A A c2 A B + + A B + B B B B Cs A' A! 2A! 2A' A" A" 2A" 2A" A' A! A A! Cs A1 A" + A" A9 + + A" A" A" A" * The coefficient 2 is not to be used in this correlation method; see p. 202 and Chapter 5, examples 3 and 4. 207
c. A B Ei c, A A E E c2 A B 2B* 2 A* Ci A A 2 A* 2 A* c*h Ag Elg E2g Au Bu Exu E2u C6 A B Ex A B Ex E2 c3h A' A" E" E' A" A' E' E" $6 = C3i Ag e\ Eg Au Eu E C™ A9 Bg 2B* 2A* Au Bu 2BZ 2AZ c3 A A E E A A E E c, A B 2B* 2 A* A B 2B* 2 A* Cs A' A" 2A"* 2A'* A" A' 2A'* 2A"* Ci Ag Ag 2A* 2A* Au Au 2At 2AZ Cx A A 2 A* 2 A* A A 2 A* 2 A* c«v Ax A2 Bx B2 Ex E2 c* A A B B Ex E2 c3v Ax A2 Ax A2 E E c» Ax A% Ax E E av ->■ a(zx) c2v Ax A2 Bx B2 Bt +B2 Ax + Az c3 A A A A E E c2 A A B B IB 2A A' A' <*» Cs A' A" A' A" + + A" A" A' A' c. A' A" A" A' + + A" A" A A B B E1 E2 C'z Dz A A2 A E E ci £3 A E E A Bi B3 B2 + B A + Bx C3 A A A A 3 E E c2 c2 A A B B 2B 2A A A c2 c2 A B A B + + B B A A ^2 c2 A B B A + + B B Ax Ex * The coefficient 2 is not to be used in this correlation method; see p. 202 and Chapter 5, examples 3 and 4. 208
cq 5: 5; 5: S: fc ^ ^ ^ rq rr. cq cq cq I Cq *^j cq "^ cq CM CM CM CM CM to. Cq 1^ ^d J>^ CM CM W N N <M W iH r-f cq ^ cq - oq cq t cq cq cq I cq cq I 209
to8 If b" "to" "to" \ 14) b" vr jo eo CO cf 13 CO 13 CO q co q q" qa rH CM ■^2 oq oq Q rH (M rH rH <N (M rH <N <M rH CM rH » cs o> ^ TH^H. C» Cu O) rH CM SCI ■^ "^ cq c v. ^^ (MS; (M5: ^ Hv CM5S tH*: ca b, &> ^ "^ oq c j CO s c ca (N T-[ y-( q rH: CM q CO rH j , r-f «S 53) 3 3 ^ f^ TjH TjH T ^ (^ TjH "^ T r-f CM ^] fjj TJH Trt T i-t eM co o> I S rH 3 3 jq tq ^j ^ t «^ to, ^ "^ c rH CM N rH .^q ^q ^ tjh c : ^. 5: rHt CM*. ■^ ^ "^ "^ T : v 5: tH5: <M«^ rH CM rH CM to & 3 9 -t} tt) ^ "^ C 00 (vT1 H ^J M [^ H T^ fj] Ct^ H CM r ,. ^ "^q to ^ CM rH r ,. c "^ to ^ tH_ <M CO rH cm eo . i CM 3 Sr » jh r^< tq to, S S 3 3 ^ bq bq q £q faT^ <Nv.tHv. % tH»« CM»» % d "^! to. to. rH <N rH CM q Dq tq wq 3 3 3 3 q cq tq to. 210
to O to AJ to^O" bV CM CM <M CM CM CM ear r-t GJ t-4 fiq "^ Dq "^ i-ic<itH<nj ( ear r-l r-r cq ^ a a a ^ ^s a 3^ » S 3 3 CM CM CM CM QQ oq CM ^ oq^Dq3 CM CM d t-I rH _i I r-i e5f Dq ^ 1-4 (M rH »H n ea h j 1 Dq Dq *i \ Dq1^1 211
c3i = s6 Ag Eg Au cs A E A E Q Ag 2A* Au 2AU* Cx A 2 A* A 2 A* A B c, A A E 2Z?* E c2 A A 25* 2 A* 2B* Ci A A 2 A* 2 A* 2 A* AX = V+ A2 = 1r Ex = II E2 = A E3 = 0 £4 = r ^2 -E2 B2 + B: E2 clv Ax A2 E ^1 + ^2 L ^ A + A2 CSv A A2 E E A + A E c2v A Z? 1 Z? ■oi -r ^2 A + A Bx + B2 s+ \ s~ n. .A". ^2g A Elg Ex E2g E2 A2u A^ Au A 77" 771 ^2u £2 ^2 Ax A, E E Alg A2g K Blg + B2 Azu Alu Eu civ Ax A2 E o Bx + B2 Ax A2 E „ Bx-\- Be, A 2+ = ax A2 S~ = ^2 ^i + B2 U^E1 Ax + A2 A == E2 ^ s+ = Ax A V— — J ^ + .b2 n = j?! T A E F D2 A 2 A* Bx -f B2 + B3 Cs A E A + Et A 2 A* A + 2B Ci A 2 A* 3A * The coefficient 2 is not to be used in this correlation method; see p. and Chapter 1, examples 3 and 4. f The z axis of C^v and D^n groups must coincide with z axis of point group. t p. 202, add the coefficient 2 to E{ species. 212
A A2 E Fx F2 T A A E F F A A B2 D2c A + + + i Bx E E c3v A, E A2 + A + E E A A B A B + + B E Bx- ^2 A A 2A hB2 + l \-B2 + i 53 A- c2v A k + A - &i + B2 f Bx + B2 A A c3 A A E + + E E A A c2 A A 2A + 2B + 2B A' A' 2A' Cs A! A!1 + + + A" 2A" A" Dt 2h A E F A E F 2Ag* Z 2AU* A 2A* A2 2A* 2Ag* A** Au + 2BU A E A 2,4* A + 2B A 2A* A + 2B A' 2Af* A' + 2A" A" 2A"* 2A! + A!' * The coefficient 2 is not to be used in this correlation method; see p. j 53and Chapter 5, examples 3 and 4. J p. 202, add the coefficient 2 to E{ species. 2A* SAn 3AU A 2A* 3A A 2A* SA
0 A A E E2 T A A E F F A A B* A Bx + Bt + E + E A A A A E s + L + E E A A B Q A B + + B JCj Jj D2 A A 2A ±+B2 + l X+B2 + 1 C2, 2C2 A Bx A + Bx 53 B1 + B2 + i 3Z A + B2 + B 33 A 3 A c* A A E + + E E A A c2 A A 2A + 2B + 2B A A 2A c, A B + + + B 2B B On Alg E F1 FZg AL A2u E Fxu CORRELATION TABLE FOR Oh AND 0 At A E Ft F2 Ax A E Td A A E Fx A A E F2 Ft A A Fg Au A Fu T A A E F F A A E F F J>.d D* C3V A A A rp a i^ n rp ^9 ^19 "t" nlg ■& 2g i" &g A2g -f- tLg A2 -f- Ag H" Eg B2g + Eg A1Jr Au Biu A Eu Alu -f- Blu E Au + Eu A2u + Eu Ax + Alu + Eu B2u + Eu A2 + ITS E A E A E A E A SUBGROUPS ^3 A E 2 + 1 + Ax A* E 2 + 1 + E E E E Ag Ag Au Aa -s. Ag Ag + Eg + E9 Au Au Eu + eI
I? 1? * oaq -^ fiq ^ cq rH r-i ^ cq rH r-i ^ cq cq cq + «f ^* CqH rH rH cq of T-f rH cq to. to, to, + +^ ^ cq to. to. (M 93 + +0 tq bq ©a e<i to, to. cq oq cqS 3 cq" r-t rH i ^ cq i rH q cq + 93 rH cq rH ea | q ^ + 03 ccT rH cj "^d to cq cq + + + oq 3 + to. ©3 ft) IT CO ^ Jo" IT CM *3 CO ^H CM c? rH rH . H (M ^of + to CM eo cq + + CO cq + tH cq «T •+ cq* i of cq ^r cq cq^ + G) cq^ cq of "t of 'ft? CO cq + cq" CO cq + cq" + C3 rH rH cq + cq t to cq + cq^ Co cqW ~t of cq" co eo cq cq cqM+ + t^ ftj*_[_of cq1 ^ + + CO CO cq cq £\| ^M **H r-i rH cq cq of of «f++ ^■of+of^ cq cq ^•V + «fof N N « «j _i CM co 3 o^H- + ^ cq "t Qq Q2* 3 ^ cq ^q 3 3 cq cq 3 3 3 3 3 ^ ^ 5 of of 3 3 of of 215
' CM CO CO CM CO CO cq cm ^Q ^q cm ^Q CM CM CM ^ CM "^ CM CM i ^ 4.°* * * fe ' CM v. 4" CM . [CM 3 » 3CM CM o CMCMCMCMCMCMCMCM CM CM CO CO CM CM CM CM ^ 216
AUTHOR INDEX Adama, D. M., 37, 171 Antion,D. J., 170 Bentley, F. F., 1 Bhagavantam, S., 1, 53 Bunn, C. W., 146 Corradini, P., 149,155 Cross, P. C, 170, 181 Decius,J. C, 170, 181 Durig,J.R., 25,31,171 Fateley, W. G., 1 Frevel, L. K., 117 Halford, R. S., 1,145, 171 Henry, N.F.M., 170 Herzberg, G., 65, 86, 171 Higgs,P.W., 155 Hornig,D.F., 1,171 Khanna, R. K., 170 Kittel,C, 170 Koenig,J. L., 163 Krimm,S., 155 Liang, C.Y., 155 Lonsdale,K., 170 McDevitt, N. T., 1 Natta,G., 149,155 Reimann, C. W., 170 Slater, J. S., 170 Tadokoro, H., 155 217
218 Author Index Tobin, M., 145 Wilson, E. B., 170, 181 Tuinstra, F., 163 Winston, H., 1,145, 171 Wyckoff, R.W.C., 170 Venkatarayudu, T., 1, 53 Zbinden,R., 145
SUBJECT INDEX Aluminum oxide, alpha, 3,4, 7, 23, 37 aluminum atom, 23 lattice vibrations, 23 equivalent atom-site, 23 infrared activity, 24 oxygen atom, 24 lattice vibration, 24 raman activity, 24 Ammonium azide, 117 ammonium ion, 119 intramolecular vibrations, 120 lattice vibration, 119 libration, 119 irreducible representation for, 124 Ammonium iodide, 3, 7, 25 acoustical vibrations, 32 intramolecular vibrations, 32 iodine ion, 29 infrared activity, 29 lattice vibrations, 29 raman activity, 29 lattice vibrations, 29 NHj ion, 26,42,43 infrared activity, 28 intramolecular vibrations, 31 lattice vibrations, 26 raman activity, 28 rotations, 30 rotational vibrations, 32 Ammonium ion, 79 hydrogen atom, 83 activity, 83 intramolecular activity, 83 nitrogen atom, 84 activity, 84 Aragonite structure, 165 Axis of gravity, 145 219
220 Subject Index azide ions, 120 intramolecular vibrations, 122 ions in site a, 121 ions in sitefe, 122 Benzene, 66 hydrogen atoms, 68 activity, 68 infrared activity, 69 raman activity, 69 site symmetry, 61 Bixybyite structure, 133 lattice vibrations, 135 separable degeneracy, 133 site symmetries, 133 Boron carbide, 130 irreducible representation, 132 site symmetries, 130 Bravais, space cell, 2, 3, 4,181 cell, 4,12,37 Brillouin zone, 17 Calcite structure, 167 Calcium carbonate, 165, 167 Calcium fluoride, 169 Center of gravity, 145 Character tables, 181 Chlorobenzene, 76 infrared activity, 78 raman activity, 78 site symmetries, 76 Correlation tables, 14 derivative, 37 relationship to site notation, 43 Crystal structure, 2 Cuprous oxide, 3, 4, 6, 7, 21 copper atom, 22 lattice vibrations, 22 equivalent atom-site, 21 infrared activity, 22 oxygen atom, 22 lattice vibrations, 22 raman activity, 22 1,4-Dichlorobenzene, 73 hydrogen atoms, 75 activity, 75 infrared activity, 73 raman activity, 73 site symmetries, 73 Equivalent atoms, 5 External vibrations, 26 Fluorite structure, 169 Garnet structure, 138 AlO4ion, 142 internal vibrations, 143 lattice, 143 libration, 142 A1O6 ion, 144 lattice vibrations, 140 site symmetries, 138 Graphite, 162 interaction between layers, 163 activity, 164 isolated layer, 162 intramolecular vibrations, 162 Helical axis, 155 Helical molecules, 155 general, 158 Ilmenite structure, 166 Internal vibrations, 26 Intramolecular vibrations, 25
Subject Index 221 irreducible representations, 65 nongenuine motions, 66 Ironsulfide, 168 Iron titanate, 166 Irreducible representation, 12,13 Lattice points, 3 Lattice vibrations, 2, 9,13,14 Libration, 25 Molecular crystal, 13 Molecular selection rules, 65 Perovskite, 54 Polarizability tensor, 28 Polyethylene, 146 irreducible representation, 149 line group, 146 activity, 148 Polyethylene oxide, 156 irreducible representation, 158 Polyvinylchloride, syndiotatic, 149 intramolecular vibrations, 153 irreducible representation, 154 Potassium hydrogen bifluoride, 125 ionic crystal, 129 with molecular ion, 127 intramolecular vibration, 129 irreducible representation, 130 libration of, 128 Pyrite structure, 168 Raman interactions, 87 References, 170 Rotational freedom, 10 Rotations, 9 improper, 54 polymer chain, 148, 152 proper, 54 Rutile structure, 165 Separable degeneracy, 10,11 example, 133 Site symmetry, 4, 5, 35 equivalent sets of atoms, 66 tables, 181 Spinel structure, 169 Strontium titanate, 3, 7,18, 54 equivalent atom-site, 20 infrared activity, 21 irreducible representation, 53, 64 oxygen atom, 21 lattice vibrations, 21 raman activity, 21, 64 strontium atom, 20 lattice vibrations, 20 titanium atom, 20 lattice vibrations, 20 Titanium dioxide, 165 acoustical vibrations, 17 anatase, 3, 6, 7, 15,16,18, 19,35, 36,42,43,166 equivalent atom-site, 7 infrared activity, 18 lattice vibrations, 16 oxygen atom, 16,36,43 raman activity, 18 titanium atom, 8, 13,15, 36 vibrational displacements, 8 lattice vibrations, 15 Translations, 9 polymer chain, 148,152 1,3,5-Trichlorobenzene, 69 activity, 72 chlorine atoms, 72
222 Subject Index infrared activity, 71 raman activity, 71 site symmetries, 69 Unit cell, crystallographic, 2,4, 37 Vibrational freedom, 10 Wurtzite structure, 167 Wyckoff, tables, 35, 37 notation, 36, 38,43 Zinc blende structure, 168 Zincsulfide, 167,168 Zirconium dioxide, 3, 24 equivalent atom-site, 24 infrared activity, 25 oxygen atom, 25 lattice vibrations, 25 raman activity, 25 zirconium atom, 25 lattice vibrations, 25