Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

28.2 FINITE GROUPS


28.2 Finite groups

Whilst many properties of physical systems (e.g. angular momentum) are related


to the properties of infinite, and, in particular, continuous groups, the symmetry


properties of crystals and molecules are more intimately connected with those of


finite groups. We therefore concentrate in this section on finite sets of objects that


can be combined in a way satisfying the group postulates.


Although it is clear that the set of all integers does not form a group under

ordinary multiplication, restricted sets can do so if the operation involved is multi-


plication (modN) for suitable values ofN; this operation will be explained below.


As a simple example of a group with only four members, consider the setS

defined as follows:


S={ 1 , 3 , 5 , 7 } under multiplication (mod 8).

To find the product (mod 8) of any two elements, we multiply them together in


the ordinary way, and then divide the answer by 8, treating the remainder after


doing so as the product of the two elements. For example, 5×7 = 35, which on


dividing by 8 gives a remainder of 3. Clearly, sinceY×Z=Z×Y, the full set


of different products is


1 ×1=1, 1 ×3=3, 1 ×5=5, 1 ×7=7,
3 ×3=1, 3 ×5=7, 3 ×7=5,
5 ×5=1, 5 ×7=3,
7 ×7=1.

The first thing to notice is that each multiplication produces a member of the


original set, i.e. the set is closed. Obviously the element 1 takes the role of the


identity, i.e. 1×Y=Yfor all membersYof the set. Further, for each elementY


of the set there is an elementZ(equal toY, as it happens, in this case) such that


Y×Z= 1, i.e. each element has an inverse. These observations, together with the


associativity of multiplication (mod 8), show that the setSis an Abelian group


of order 4.


It is convenient to present the results of combining any two elements of a

group in the form of multiplication tables – akin to those which used to appear in


elementary arithmetic books before electronic calculators were invented! Written


in this much more compact form the above example is expressed by table 28.1.


Although the order of the two elements being combined does not matter here


because the group is Abelian, we adopt the convention that if the product in a


general multiplication table is writtenX•YthenXis taken from the left-hand


column andYis taken from the top row. Thus the bold ‘ 7 ’ in the table is the


result of 3×5, rather than of 5×3.


Whilst it would make no difference to the basic information content in a table

to present the rows and columns with their headings in random orders, it is

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