Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

11.8 DIVERGENCE THEOREM AND RELATED THEOREMS


Sincevhas a singularity at the origin it is not differentiable there, i.e.∇·vis not

defined there, but at all other points∇·v= 0, as required for an incompressible


fluid. Therefore, from the divergence theorem, for any closed surfaceS 2 that does


not enclose the origin we have


S 2

v·dS=


V

∇·vdV=0.

Thus we see that the surface integral


Sv·dShas valueQor zero depending
on whether or notSencloses the source. In order that the divergence theorem is


valid forallsurfacesS, irrespective of whether they enclose the source, we write


∇·v=Qδ(r),

whereδ(r) is the three-dimensional Dirac delta function. The properties of this


function are discussed fully in chapter 13, but for the moment we note that it is


defined in such a way that


δ(r−a)=0 forr=a,


V

f(r)δ(r−a)dV=

{
f(a)ifalies inV

0otherwise

for any well-behaved functionf(r). Therefore, for any volumeVcontaining the


source at the origin, we have


V

∇·vdV=Q


V

δ(r)dV=Q,

which is consistent with



Sv·dS=Qfor a closed surface enclosing the source.
Hence, by introducing the Dirac delta function the divergence theorem can be


made valid even for non-differentiable point sources.


The generalisation to several sources and sinks is straightforward. For example,

if a source is located atr=aand a sink atr=bthen the velocity field is


v=

(r−a)Q
4 π|r−a|^3


(r−b)Q
4 π|r−b|^3

and its divergence is given by


∇·v=Qδ(r−a)−Qδ(r−b).

Therefore, the integral



Sv·dShas the valueQifSencloses the source,−Qif
Sencloses the sink and 0 ifSencloses neither the source nor sink or encloses


them both. This analysis also applies to other physical systems – for example, in


electrostatics we can regard the sources and sinks as positive and negative point


charges respectively and replacevby the electric fieldE.

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