LINE, SURFACE AND VOLUME INTEGRALS
which shows that we requirea·drto be an exact differential: condition (iv). From
(10.27) we can writedφ=∇φ·dr, and so we have
(a−∇φ)·dr=0.Sincedris arbitrary, we find thata=∇φ; this immediately implies∇×a= 0 ,
condition (iii) (see (10.37)).
Alternatively, if we suppose that there exists a single-valued function of positionφsuch thata=∇φthen∇×a= 0 follows as before. The line integral around a
closed loop then becomes
∮
Ca·dr=∮C∇φ·dr=∮
dφ.Since we definedφto be single-valued, this integral is zero as required.
Now suppose∇×a= 0. From Stoke’s theorem, which is discussed in sec-tion 11.9, we immediately obtain
∮
Ca·dr=0;thena=∇φanda·dr=dφfollow
as above.
Finally, let us supposea·dr=dφ. Then immediately we havea=∇φ,andtheother results follow as above.
Evaluate the line integralI=∫B
Aa·dr,wherea=(xy(^2) +z)i+(x (^2) y+2)j+xk,Ais the
point(c, c, h)andBis the point(2c, c/ 2 ,h), along the different paths
(i)C 1 ,givenbyx=cu,y=c/u,z=h,
(ii)C 2 ,givenby 2 y=3c−x,z=h.
Show that the vector fieldais in fact conservative, and findφsuch thata=∇φ.
Expanding out the integrand, we have
I=
∫(2c, c/ 2 ,h)(c, c, h)[
(xy^2 +z)dx+(x^2 y+2)dy+xdz]
, (11.7)
which we must evaluate along each of the pathsC 1 andC 2.
(i) AlongC 1 we havedx=cdu,dy=−(c/u^2 )du,dz= 0, and on substituting in (11.7)
and finding the limits onu,weobtain
I=
∫ 2
1c(
h−2
u^2)
du=c(h−1).(ii) AlongC 2 we have 2dy=−dx,dz= 0 and, on substituting in (11.7) and using the
limits onx,weobtain
I=
∫ 2 cc( 1
2 x(^3) − 9
4 cx
(^2) + 9
4 c
(^2) x+h− 1 )dx=c(h−1).
Hence the line integral has the same value along pathsC 1 andC 2. Taking the curl ofa,
we have
∇×a=(0−0)i+(1−1)j+(2xy− 2 xy)k= 0 ,
soais a conservative vector field, and the line integral between two points must be