GROUP THEORY
ifHis anormalsubgroup ofGthen its (left) cosets themselves form a group (see
exercise 28.16).
28.7.3 Conjugates and classesOur second example of an equivalence relation is concerned with those elements
XandYof a groupGthat can be connected by a transformation of the form
Y=G−i^1 XGi,whereGiis an (appropriate) element ofG. ThusX∼Yif there
exists an elementGiofGsuch thatY=G−i^1 XGi. Different pairs of elementsX
andYwill, in general, require different group elementsGi. Elements connected
in this way are said to beconjugates.
We first need to establish that this does indeed define an equivalence relation,as follows.
(i) Reflexivity:X∼X,sinceX=I−^1 XIandIbelongs to the group.
(ii) Symmetry:X∼YimpliesY=G−i^1 XGiand thereforeX=(G−i^1 )−^1 YG−i^1.
SinceGibelongs toGso doesG−i^1 , and it follows thatY∼X.
(iii) Transitivity:X∼YandY∼ZimplyY=G−i^1 XGiandZ=G−j^1 YGj
and thereforeZ=G−j^1 G−i^1 XGiGj=(GiGj)−^1 X(GiGj). SinceGiandGj
belong toGso doesGiGj, from which it follows thatX∼Z.These results establish conjugacy as an equivalence relation and hence showthat it dividesGinto classes, two elements being in the same class if, and only if,
they are conjugate.
Immediate corollaries are:(i) IfZis in the class containingIthenZ=G−i^1 IGi=G−i^1 Gi=I.Thus, since any conjugate ofIcanbeshowntobeI, the identity must be
in a class by itself.
(ii) IfXis in a class by itself thenY=G−i^1 XGimust imply thatY=X.ButX=GiG−i^1 XGiG−i^1for anyGi,andsoX=Gi(Gi−^1 XGi)G−i^1 =GiYG−i^1 =GiXG−i^1 ,i.e.XGi=GiXfor allGi.
Thus commutation with all elements of the group is a necessary (and
sufficient) condition for any particular group element to be in a class by
itself. In an Abelian group each element is in a class by itself.