Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

26.10 IMPROPER ROTATIONS AND PSEUDOTENSORS


O O


p

v

x 1

x 2

x 3

x′ 1

x′ 2

x′ 3

v′

p′

Figure 26.2 The behaviour of a vectorvand a pseudovectorpunder a
reflection through the origin of the coordinate systemx 1 ,x 2 ,x 3 giving the new
systemx′ 1 ,x′ 2 ,x′ 3.

It is important to realise that a pseudovector (as its name suggests) is not a

geometrical object in the usual sense. In particular, it shouldnotbe considered


as a real physical arrow in space, since its direction is reversed by animproper


transformation of the coordinate axes (such as an inversion through the origin).


This is illustrated in figure 26.2, in which the pseudovectorpis shown as a broken


line to indicate that it is not a real physical vector.


Corresponding to vectors and pseudovectors, zeroth-order objects may be

divided into scalars and pseudoscalars – the latter being invariant under rotation


but changing sign on reflection.


We may also extend the notion of scalars and pseudoscalars, vectors and pseu-

dovectors, to objects with two or more subscripts. For two subcripts, as defined


previously, any quantity with components that transform asTij′=LikLjlTklun-


derallrotations (proper and improper) is called a second-order Cartesian tensor.


If, however,Tij′=LikLjlTklunder proper rotations butTij′=−LikLjlTklunder


improper ones (which include reflections), then theTijare the components of


a second-order Cartesian pseudotensor. In general the components of Cartesian


pseudotensors of arbitary order transform as


Tij′···k=|L|LilLjm···LknTlm···n, (26.39)

where|L|is the determinant of the transformation matrix.


For example, from (26.29) we have that

|L|ijk=LilLjmLknlmn,
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