Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

25.1 COMPLEX POTENTIALS


P


Q


y

x


Figure 25.2 A curve joining the pointsPandQ. Also shown isˆn, the unit
vector normal to the curve.

the difference in the values ofψat any two pointsPandQconnected by some


pathC, as shown in figure 25.2. This difference is given by


ψ(Q)−ψ(P)=

∫Q

P

dψ=

∫Q

P

(
∂ψ
∂x

dx+

∂ψ
∂y

dy

)
,

which, on using the Cauchy–Riemann relations, becomes


ψ(Q)−ψ(P)=

∫Q

P

(

∂φ
∂y

dx+

∂φ
∂x

dy

)

=

∫Q

P

∇φ·nˆds=

∫Q

P

∂φ
∂n

ds,

whereˆnis the vector unit normal to the pathCandsis the arc length along the


path; the last equality is written in terms of the normal derivative∂φ/∂n≡∇φ·ˆn.


Now suppose that in an electrostatics application, the pathCis the surface of

a conductor; then


∂φ
∂n

=−

σ
 0

,

whereσis the surface charge density per unit length normal to thexy-plane.


Therefore− 0 [ψ(Q)−ψ(P)] is equal to the charge per unit length normal to the


xy-plane on the surface of the conductor between the pointsPandQ. Similarly,


in fluid mechanics applications, if the density of the fluid isρand its velocity is


Vthen


ρ[ψ(Q)−ψ(P)] =ρ

∫Q

P

∇φ·nˆds=ρ

∫Q

P

V·ˆnds

is equal to the mass flux betweenPandQper unit length perpendicular to the


xy-plane.

Free download pdf