LINE, SURFACE AND VOLUME INTEGRALS
ydca b xS R
T
C
U
V
Figure 11.3 A simply connected regionRbounded by the curveC.These ideas can be extended to regions that are not planar, such as generalthree-dimensional surfaces and volumes. The same criteria concerning the shrink-
ing of closed curves to a point also apply when deciding the connectivity of such
regions. In these cases, however, the curves must lie in the surface or volume
in question. For example, the interior of a torus is not simply connected, since
there exist closed curves in the interior that cannot be shrunk to a point without
leaving the torus. The region between two concentric spheres of different radii is
simply connected.
11.3 Green’s theorem in a planeIn subsection 11.1.1 we considered (amongst other things) the evaluation of line
integrals for which the pathCis closed and lies entirely in thexy-plane. Since
the path is closed it will enclose a regionRof the plane. We now discuss how to
express the line integral around the loop as a double integral over the enclosed
regionR.
Suppose the functionsP(x, y),Q(x, y) and their partial derivatives are single-valued, finite and continuous inside and on the boundaryCof some simply
connected regionRin thexy-plane.Green’s theorem in a plane(sometimes called
the divergence theorem in two dimensions) then states
∮C(Pdx+Qdy)=∫∫R(
∂Q
∂x−∂P
∂y)
dx dy, (11.4)and so relates the line integral aroundCto a double integral over the enclosed
regionR. This theorem may be proved straightforwardly in the following way.
Consider the simply connected regionRin figure 11.3, and lety=y 1 (x)and