21.5 INHOMOGENEOUS PROBLEMS – GREEN’S FUNCTIONS
ˆn nˆnˆV
V S
S 1
S 2
(a) (b)Figure 21.11 Surfaces used for solving Poisson’s equation in different
regionsV.where on the RHS it is common to write, for example,∇ψ·nˆdSas (∂ψ/∂n)dS.
The expression∂ψ/∂nstands for∇ψ·nˆ, the rate of change ofψin the direction
of the unit outward normalnˆto the surfaceS.
The Green’s function for Poisson’s equation (21.80) must satisfy∇^2 G(r,r 0 )=δ(r−r 0 ), (21.82)wherer 0 lies inV. (As mentioned above, we may think ofG(r,r 0 )asthesolution
to Poisson’s equation for a unit-strength point source located atr=r 0 .) Let us
for the moment impose no boundary conditions onG(r,r 0 ).
If we now letφ=u(r)andψ=G(r,r 0 ) in Green’s theorem (21.81) then weobtain
∫
V[
u(r)∇^2 G(r,r 0 )−G(r,r 0 )∇^2 u(r)]
dV(r)=∫S[
u(r)∂G(r,r 0 )
∂n−G(r,r 0 )∂u(r)
∂n]
dS(r),where we have made explicit that the volume and surface integrals are with
respect tor. Using (21.80) and (21.82) the LHS can be simplified to give
∫
V[u(r)δ(r−r 0 )−G(r,r 0 )ρ(r)]dV(r)=∫S[
u(r)∂G(r,r 0 )
∂n−G(r,r 0 )∂u(r)
∂n]
dS(r). (21.83)Sincer 0 lies within the volumeV,
∫
Vu(r)δ(r−r 0 )dV(r)=u(r 0 ),and thus on rearranging (21.83) the solution to Poisson’s equation (21.80) can be