Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

29.10 PRODUCT REPRESENTATIONS


give a large selection of character tables; our aim is to demonstrate and justify


the use of those found in the literature specifically dedicated to crystal physics or


molecular chemistry.


Variations in notation are not restricted to the naming of groups and their

irreps, but extend to the symbols used to identify a typical element, and hence


all members, of a conjugacy class in a group. In physics these are usually of the


typesnz, ̄nzormx. The first of these denotes a rotation of 2π/nabout thez-axis,


and the second the same thing followed by parity inversion (all vectorsrgo to


−r), whilst the third indicates a mirror reflection in a plane, in this case the plane


x=0.


Typical chemistry symbols for classes areNCn,NC^2 n,NCnx,NSn,σv,σxy.Here

the first symbolN, where it appears, shows that there areNelements in the


class (a useful feature). The subscriptnhas the same meaning as in the physics


notation, butσrather thanmis used for a mirror reflection, subscriptsv,dorhor


superscriptsxy,xzoryzdenoting the various orientations of the relevant mirror


planes. Symmetries involving parity inversions are denoted byS; thusSnis the


chemistry analogue of ̄n. None of what is said in this and the previous paragraph


should be taken as definitive, but merely as a warning of common variations in


nomenclature and as an initial guide to corresponding entities. Before using any


set of group character tables, the reader should ensure that he or she understands


the precise notation being employed.


29.10 Product representations

In quantum mechanical investigations we are often faced with the calculation of


what are called matrix elements. These normally take the form of integrals over all


space of the product of two or more functions whose analytic forms depend on the


microscopic properties (usually angular momentum and its components) of the


electrons or nuclei involved. For ‘bonding’ calculations involving ‘overlap integrals’


there are usually two functions involved, whilst for transition probabilities a third


function, giving the spatial variation of the interaction Hamiltonian, also appears


under the integral sign.


If the environment of the microscopic system under investigation has some

symmetry properties, then sometimes these can be used to establish, without


detailed evaluation, that the multiple integral must have zero value. We now


express the essential content of these ideas in group theoretical language.


Suppose we are given an integral of the form

J=


Ψφdτ or J=


Ψξφ dτ

to be evaluated over all space in a situation in which the physical system is


invariant under a particular groupGof symmetry operations. For the integral to

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