Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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GROUP THEORY


It is clear that cyclic groups are always Abelian and that each element, apart


from the identity, has orderg, the order of the group itself.


28.1.2 Further examples of groups

In this section we consider some sets of objects, each set together with a law of


combination, and investigate whether they qualify as groups and, if not, why not.


We have already seen that the integers form a group under ordinary addition,

but it is immediately apparent that (even if zero is excluded) they donotdo


so under ordinary multiplication. Unity must be the identity of the set, but the


requisite inverse of any integern,namely1/n, does not belong to the set of


integers for anynother than unity.


Other infinite sets of quantities that do form groups are the sets of all real

numbers, or of all complex numbers, under addition, and of the same two sets


excluding 0 under multiplication. All these groups are Abelian.


Although subtraction and division are normally considered the obvious coun-

terparts of the operations of (ordinary) addition and multiplication, they are not


acceptable operations for use within groups since the associative law, (28.1), does


not hold. Explicitly,


X−(Y−Z)=(X−Y)−Z,

X÷(Y÷Z)=(X÷Y)÷Z.

From within the field of all non-zero complex numbers we can select just those

that have unit modulus, i.e. are of the formeiθwhere 0≤θ< 2 π,toforma


group under multiplication, as can easily be verified:


eiθ^1 ×eiθ^2 =ei(θ^1 +θ^2 ) (closure),
ei^0 = 1 (identity),
ei(2π−θ)×eiθ=ei^2 π≡ei^0 = 1 (inverse).

Closely related to the above group is the set of 2×2 rotation matrices that take


the form


M(θ)=

(
cosθ −sinθ
sinθ cosθ

)

where, as before, 0≤θ< 2 π. These form a group when the law of combination


is that of matrix multiplication. The reader can easily verify that


M(θ)M(φ)=M(θ+φ) (closure),
M(0) =I 2 (identity),
M(2π−θ)=M−^1 (θ) (inverse).

HereI 2 is the unit 2×2 matrix.

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