Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

REPRESENTATION THEORY


a representation in which all the matrices are unitary (see chapter 8) and so from


now on we will consider onlyunitary representations.


29.4 Reducibility of a representation

We have seen already that it is possible to have more than one representation


of any particular group. For example, the group{ 1 ,i,− 1 ,−i}under ordinary


multiplication has been shown to have a set of 2×2 matrices, and a set of four


unitn×nmatricesIn, as two of its possible representations.


Consider two or more representations,D(1), D(2), ...,D(N), which may be

of different dimensions, of a groupG. Now combine the matricesD(1)(X),


D(2)(X), ...,D(N)(X) that correspond to elementXofGinto a largerblock-


diagonalmatrix:


D

(2)
(X)

D(N)(X)

...


D(X) =

0


0
D

(1)
(X)

(29.9)

ThenD={D(X)}is the matrix representation of the group obtained by combining


the basis vectors ofD(1),D(2), ...,D(N)into one larger basis vector. If, knowingly or


unknowingly, we had started with this larger basis vector and found the matrices


of the representationDto have the form shown in (29.9), or to have a form


that can be transformed into this by a similarity transformation (29.5) (using,


of course, thesamematrixQfor each of the matricesD(X)) then we would say


thatDisreducibleand that each matrixD(X) can be written as thedirect sumof


smaller representations:


D(X)=D(1)(X)⊕D(2)(X)⊕···⊕D(N)(X).

It may be that some or all of the matricesD(1)(X),D(2)(X), ...,D(N)themselves

can be further reduced – i.e. written in block diagonal form. For example,


suppose that the representationD(1), say, has a basis vector (xyz)T; then, for


the symmetry group of an equilateral triangle, whilstxandyare mixed together


for at least one of the operationsX,zis never changed. In this case the 3× 3


representative matrixD(1)(X) can itself be written in block diagonal form as a

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