Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

GROUP THEORY


if matrices are involved. In the notation in whichG={G 1 ,G 2 ,...,Gn}the order


of the group is clearlyn.


As we have noted, for the integers under addition zero is the identity. For

the group of rotations and reflections, the operation of doing nothing, i.e. the


null operation, plays this role. This latter identification may seem artificial, but


it is an operation, albeit trivial, which does leave the system in a physically


indistinguishable state, and needs to be included. One might add that without it


the set of operations would not form a group and none of the powerful results


we will derive later in this and the next chapter could be justifiably applied to


give deductions of physical significance.


In the examples of rotations and reflections mentioned earlier,•has been taken

to mean that the left-hand operation is carried out on the system that results


from application of the right-hand operation. Thus


Z=X•Y (28.4)

means that the effect on the system of carrying outZisthesameaswould


be obtained by first carrying outYand then carrying outX. The order of the


operations should be noted; it is arbitrary in the first instance but, once chosen,


must be adhered to. The choice we have made is dictated by the fact that most


of our applications involve the effect of rotations and reflections on functions of


space coordinates, and it is usual, and our practice in the rest of this book, to


write operators acting on functions to the left of the functions.


It will be apparent that for the above-mentioned group, integers under ordinary

addition, it is true that


Y•X=X•Y (28.5)

for all pairs of integersX,Y. If any two particular elements of a group satisfy


(28.5), they are said tocommuteunder the operation•; if all pairs of elements in


a group satisfy (28.5), then the group is said to beAbelian.Thesetofallintegers


forms an infinite Abelian group under (ordinary) addition.


As we show below, requirements (iii) and (iv) of the definition of a group

are over-demanding (but self-consistent), since in each of equations (28.2) and


(28.3) the second equality can be deduced from the first by using the associativity


required by (28.1). The mathematical steps in the following arguments are all


very simple, but care has to be taken to make sure that nothing that has not


yet been proved is used to justify a step. For this reason, and to act as a model


in logical deduction, a reference in Roman numerals to the previous result,


or to the group definition used, is given over each equality sign. Such explicit


detailed referencing soon becomes tiresome, but it should always be available if


needed.

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