24.2 THE CAUCHY–RIEMANN RELATIONS
Sincexandyare related tozand its complex conjugatez∗byx=1
2(z+z∗)andy=1
2 i(z−z∗), (24.6)we may formally regard any functionf=u+ivas a function ofzandz∗, rather
thanxandy. If we do this and examine∂f/∂z∗we obtain
∂f
∂z∗=∂f
∂x∂x
∂z∗+∂f
∂y∂y
∂z∗=(
∂u
∂x+i∂v
∂x)(
1
2)
+(
∂u
∂y+i∂v
∂y)(
−1
2 i)=1
2(
∂u
∂x−∂v
∂y)
+i
2(
∂v
∂x+∂u
∂y). (24.7)
Now, iffis analytic then the Cauchy–Riemann relations (24.5) must be satisfied,
and these immediately give that∂f/∂z∗is identically zero. Thus we conclude that
iffis analytic thenfcannot be a function ofz∗and any expression representing
an analytic function ofzcan containxandyonly in the combinationx+iy,not
in the combinationx−iy.
We conclude this section by discussing some properties of analytic functionsthat are of great practical importance in theoretical physics. These can be obtained
simply from the requirement that the Cauchy–Riemann relations must be satisfied
by the real and imaginary parts of an analytic function.
The most important of these results can be obtained by differentiating thefirst Cauchy–Riemann relation with respect to one independent variable, and the
second with respect to the other independent variable, to obtain the two chains
of equalities
∂
∂x(
∂u
∂x)
=∂
∂x(
∂v
∂y)
=∂
∂y(
∂v
∂x)
=−∂
∂y(
∂u
∂y)
,∂
∂x(
∂v
∂x)
=−∂
∂x(
∂u
∂y)
=−∂
∂y(
∂u
∂x)
=−∂
∂y(
∂v
∂y)
.Thus bothuandvareseparatelysolutions of Laplace’s equation in two dimen-
sions, i.e.
∂^2 u
∂x^2+∂^2 u
∂y^2= 0 and∂^2 v
∂x^2+∂^2 v
∂y^2=0. (24.8)We will make significant use of this result in the next chapter.
A further useful result concerns the two families of curvesu(x, y) = constantandv(x, y) = constant, whereuandvare the real and imaginary parts of any
analytic functionf=u+iv. As discussed in chapter 10, the vector normal to the
curveu(x, y) = constant is given by
∇u=∂u
∂xi+∂u
∂yj, (24.9)