Mathematical Methods for Physics and Engineering : A Comprehensive Guide

TENSORS

and so the covariant components ofvare given byvi=∂φ/∂ui. In (26.97),

however, we require the contravariant componentsvi. These may be obtained by

raising the index using the metric tensor, to give

vj=gjkvk=gjk

∂φ

∂uk

.

Substituting this into (26.97) we obtain

∇^2 φ=

1

√

g

∂

∂uj

(

√

ggjk

∂φ

∂uk

)

. (26.98)

Use (26.98) to find the expression for∇^2 φin an orthogonal coordinate system with scale

factorshi,i=1, 2 , 3.

For an orthogonal coordinate system

√

g=h 1 h 2 h 3 ;further,gij=1/h^2 iifi=jandgij=0
otherwise. Therefore, from (26.98) we have

∇^2 φ=

1

h 1 h 2 h 3

∂

∂uj

(

h 1 h 2 h 3

h^2 j

∂φ

∂uj

)

,

which agrees with the results of section 10.10.

Curl

The special vector form of the curl of a vector field exists only in three dimensions.

We therefore consider a more general form valid in higher-dimensional spaces as

well. In a general space the operation curlvis defined by

(curlv)ij=vi;j−vj;i,

which is an antisymmetric covariant tensor.

In fact the difference of derivatives can be simplified, since

vi;j−vj;i=

∂vi

∂uj

−Γlijvl−

∂vj

∂ui

+Γljivl

=

∂vi

∂uj

−

∂vj

∂ui

,

where the Christoffel symbols have cancelled because of their symmetry properties.

Thus curlvcan be written in terms of partial derivatives as

(curlv)ij=

∂vi

∂uj

−

∂vj

∂ui

.

Generalising slightly the discussion of section 26.17, in three dimensions we may

associate with this antisymmetric second-order tensor a vector with contravariant

components,

(∇×v)i=−

1

2

√

g

ijk(curlv)jk

=−

1

2

√

g

ijk

(

∂vj

∂uk

−

∂vk

∂uj

)

=

1

√

g

ijk

∂vk

∂uj

;