Mathematical Methods for Physics and Engineering : A Comprehensive Guide

PDES: SEPARATION OF VARIABLES AND OTHER METHODS

y

z

x

V r^0

r 1

+

−

Figure 21.12 The arrangement of images forsolving Laplace’s equation in

the half-spacez>0.

We may evaluate this normal derivative by writing the Green’s function (21.94) explicitly
in terms ofx,yandz(andx 0 ,y 0 andz 0 ) and calculating the partial derivative with respect
tozdirectly. It is usually quicker, however, to use the fact that§

∇|r−r 0 |=

r−r 0

|r−r 0 |

; (21.96)

thus

∇G(r,r 0 )=

r−r 0

4 π|r−r 0 |^3

−

r−r 1

4 π|r−r 1 |^3

.

Sincer 0 =(x 0 ,y 0 ,z 0 )andr 1 =(x 0 ,y 0 ,−z 0 ) the normal derivative is given by

−

∂G(r,r 0 )

∂z

=−k·∇G(r,r 0 )

=−

z−z 0

4 π|r−r 0 |^3

+

z+z 0

4 π|r−r 1 |^3

.

Therefore on the surfacez= 0, and writing out the dependence onx,yandzexplicitly,
we have

−

∂G(r,r 0 )

∂z

∣

∣∣

∣

z=0

=

2 z 0

4 π[(x−x 0 )^2 +(y−y 0 )^2 +z^20 ]^3 /^2

.

Inserting this expression into (21.95) we obtain the solution

u(x 0 ,y 0 ,z 0 )=

z 0

2 π

∫∞

−∞

∫∞

−∞

f(x, y)

[(x−x 0 )^2 +(y−y 0 )^2 +z^20 ]^3 /^2

dx dy.

An analogous procedure may be applied in two-dimensional problems. For

§Since|r−r 0 | (^2) =(r−r 0 )·(r−r 0 ) we have∇|r−r 0 | (^2) =2(r−r 0 ),from which we obtain
∇(|r−r 0 |^2 )^1 /^2 =^1
2
2(r−r 0 )
(|r−r 0 |^2 )^1 /^2
=r−r^0
|r−r 0 |
.
Note that this result holds in twoandthree dimensions.