Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

26.17 Relative tensors


Show that the quantitiesgij=ei·ejform the covariant components of a second-order
tensor.

In the new (primed) coordinate system we have


g′ij=e′i·e′j,

but using (26.67) for the inverse transformation, we have


e′i=

∂uk
∂u′i

ek,

and similarly fore′j.Thuswemaywrite


gij′=

∂uk
∂u′i

∂ul
∂u′j

ek·el=

∂uk
∂u′i

∂ul
∂u′j

gkl,

which shows that thegijare indeed the covariant components of a second-order tensor
(themetrictensorg).


A similar argument to that used in the above example shows that the quantities

gijform the contravariant components of a second-order tensor which transforms


according to


g′ij=

∂u′

i

∂uk

∂u′

j

∂ul

gkl.

In the previous section we discussed the use of the componentsgijandgijin

the raising and lowering of indices in contravariant and covariant vectors. This


can be extended to tensors of arbitrary rank. In general, contraction of a tensor


withgijwill convert the contracted index from being contravariant (superscript)


to covariant (subscript), i.e. it is lowered. This can be repeated for as many indices


are required. For example,


Tij=gikTkj=gikgjlTkl. (26.72)

Similarly contraction withgijraises an index, i.e.


Tij=gikTkj=gikgjlTkl. (26.73)

That (26.72) and (26.73) are mutually consistent may be shown by using the fact


thatgikgkj=δij.


26.17 Relative tensors

In section 26.10 we introduced the concept of pseudotensors in the context of the


rotation (proper or improper) of a set of Cartesian axes. Generalising to arbitrary


coordinate transformations leads to the notion of arelative tensor.


For an arbitrary coordinate transformation from one general coordinate system
Free download pdf