Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

29.7 COUNTING IRREPS USING CHARACTERS


whilst forDˆ

(λ)
=Dˆ

(μ)
= E, it gives

1(2^2 ) + 2(1) + 3(0) = 6.

(ii) ForDˆ

(λ)
=A 2 andDˆ

(μ)
= E, say, (29.15) reads

1(1)(2) + 2(1)(−1) + 3(−1)(0) = 0.

(iii) ForX 1 =AandX 2 =D, say, (29.16) reads

1(1) + 1(−1) + (−1)(0) = 0,

whilst forX 1 =CandX 2 =E, both of which belong to classC 3 for which
c 3 =3,

1(1) + (−1)(−1) + (0)(0) = 2 =

6
3

.

29.7 Counting irreps using characters

The expression of a general representationD={D(X)}in terms of irreps, as


given in (29.11), can be simplified by going from the full matrix form to that of


characters. Thus


D(X)=m 1 Dˆ

(1)
(X)⊕m 2 Dˆ

(2)
(X)⊕···⊕mNDˆ

(N)
(X)

becomes, on taking the trace of both sides,


χ(X)=

∑N

λ=1

mλχ(λ)(X). (29.17)

Given the characters of the irreps of the groupGto which the elementsXbelong,


and the characters of the representationD={D(X)},thegequations (29.17)


can be solved as simultaneous equations in themλ, either by inspection or by


multiplying both sides by


[
χ(μ)(X)

]∗
and summing overX, making use of (29.14)

and (29.15), to obtain


mμ=

1
g


X

[
χ(μ)(X)

]∗
χ(X)=

1
g


i

ci

[
χ(μ)(Xi)

]∗
χ(Xi). (29.18)

That an unambiguous formula can be given for eachmλ, once thecharacter


set(the set of characters of each of the group elements or, equivalently, of


each of the conjugacy classes) ofDis known, shows that, for any particular


group, two representations with the same characters are equivalent. This strongly


suggests something that can be shown, namely,the number of irreps = the number


of conjugacy classes.The argument is as follows. Equation (29.17) is a set of


simultaneous equations forNunknowns, themλ, some of which may be zero. The


value ofNis equal to the number of irreps ofG. There aregdifferent values of


X, but the number ofdifferentequations is only equal to the number of distinct

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