Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

26.11 Dual tensors


formations, for which the physical system of interest is left unaltered, and only


the coordinate system used to describe it is changed. In an active transformation,


however, the system itself is altered.


As an example, let us consider a particle of massmthat is located at a position

xrelative to the originOand hence has velocity ̇x. The angular momentum of


the particle aboutOis thusJ=m(x× ̇x). If we merely invert the Cartesian


coordinates used to describe this system throughO, neither the magnitude nor


direction of any these vectors will be changed, since they may be considered


simply as arrows in space that are independent of the coordinates used to de-


scribe them. If, however, we perform the analogous active transformation on


the system, by inverting the position vector of the particle throughO,thenit


is clear that the direction of particle’s velocity will also be reversed, since it


is simply the time derivative of the position vector, but that the direction of


its angular momentum vector remains unaltered. This suggests that vectors can


be divided into two categories, as follows:polarvectors (such as position and


velocity), which reverse direction under an active inversion of the physical sys-


tem through the origin, andaxialvectors (such as angular momentum), which


remain unchanged. It should be emphasised that at no point in this discus-


sion have we used the concept of a pseudovector to describe a real physical


quantity.§


26.11 Dual tensors

Although pseudotensors are not themselves appropriate for the description of


physical phenomena, they are sometimes needed; for example, we may use the


pseudotensorijkto associate with everyantisymmetricsecond-order tensorAij


(in three dimensions) a pseudovectorpigiven by


pi=^12 ijkAjk; (26.40)

piis called thedualofAij. Thus if we denote the antisymmetric tensorAby the


matrix


A=[Aij]=



0 A 12 −A 31
−A 12 0 A 23
A 31 −A 23 0



then the components of its dual pseudovector are (p 1 ,p 2 ,p 3 )=(A 23 ,A 31 ,A 12 ).


§The scalar product of a polar vector and an axial vector is a pseudoscalar. It was the experimental
detection of the dependence of the angular distribution of electrons of (polar vector) momentum
peemitted by polarised nuclei of (axial vector) spinJNupon the pseudoscalar quantityJN·pethat
established the existence of the non-conservation of parity inβ-decay.
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