LINE, SURFACE AND VOLUME INTEGRALS
11.9 Stokes’ theorem and related theoremsStokes’ theorem is the ‘curl analogue’ of the divergence theorem and relates the
integral of the curl of a vector field over an open surfaceSto the line integral of
the vector field around the perimeterCbounding the surface.
Following the same lines as for the derivation of the divergence theorem, wecan divide the surfaceSinto many small areasSiwith boundariesCiand unit
normalsnˆi. Using (11.17), we have for each small area
(∇×a)·ˆniSi≈∮Cia·dr.Summing overiwe find that on the RHS all parts of all interior boundaries
that are not part ofCare included twice, being traversed in opposite directions
on each occasion and thus contributing nothing. Only contributions from line
elements that are also parts ofCsurvive. If eachSiis allowed to tend to zero
then we obtain Stokes’ theorem,
∫S(∇×a)·dS=∮Ca·dr. (11.23)We note that Stokes’ theorem holds for both simply and multiply connected open
surfaces, provided that they are two-sided. Stokes’ theorem may also be extended
to tensor fields (see chapter 26).
Just as the divergence theorem (11.18) can be used to relate volume and surfaceintegrals for certain types of integrand, Stokes’ theorem can be used in evaluating
surface integrals of the form
∮
S(∇×a)·dSas line integrals or vice versa.Given the vector fielda=yi−xj+zk, verify Stokes’ theorem for the hemispherical
surfacex^2 +y^2 +z^2 =a^2 ,z≥ 0.Let us first evaluate the surface integral
∫
S(∇×a)·dSover the hemisphere. It is easily shown that∇×a=− 2 k, and the surface element is
dS=a^2 sinθdθdφrˆin spherical polar coordinates. Therefore
∫S(∇×a)·dS=∫ 2 π0dφ∫π/ 20dθ(
− 2 a^2 sinθ)
ˆr·k=− 2 a^2∫ 2 π0dφ∫π/ 20sinθ(za)
dθ=− 2 a^2∫ 2 π0dφ∫π/ 20sinθcosθdθ=− 2 πa^2.We now evaluate the line integral around the perimeter curveCof the surface, which