Begin2.DVI

The Curl of a Vector Field

Let F
=F
(x, y, z) = F 1 (x, y, z)ˆe 1 +F 2 (x, y, x )ˆe 2 +F 3 (x, y, z)ˆe 3 denote a continuous

vector field possessing continuous derivatives, and let P 0 denote a point in this vector

field having coordinates (x 0 , y 0 , z 0 ). Insert into this field an arbitrary surface Swhich

contains the point P 0 and construct a unit normal ˆento the surface at point P 0 .On

the surface construct a simple closed curve Cwhich encircles the point P 0 .The work

done in moving around the closed curve is called the circulation at point P 0. The

circulation is a scalar quantity and is expressed as

∫

C

©F
·d
r =Circulation of F
around Con the surface S,

where the integration is taken counterclockwise. If the circulation is divided by

the area ∆S enclosed by the simple closed curve C, then the limit of the ratio

Circulation

Area as the area ∆Stends toward zero, is called the component of the curlof

F
in the direction ˆen and is written as

( curl F
)·ˆen= lim∆S→ 0

∫

C

© F
·d
r

∆S. (8 .34)

To evaluate one component of the curlof a vector field F
at the point P 0 (x 0 , y 0 , z 0 ),

construct the plane z=z 0 which passes through P 0 and is parallel to the xy plane.

This plane has the unit normal eˆn =ˆe 3 at all points on the plane. In this plane,

consider the circulation at P 0 due to a circle of radius centered at P 0 .The equation

of this circle in parametric form is

x=x 0 +cos θ, y =y 0 +sin θ, z =z 0

and in vector form
r = (x 0 +cos θ)ˆe 1 + (y 0 +sin θ)ˆe 2 +z 0 ˆe 3 .The circulation can be

expressed as

I=

∫

C

©F
·d
r =

∫ 2 π

0

F
(x 0 +cos θ, y 0 +sin θ, z 0 ) [−sin θˆe 1 +cos θˆe 2 ]dθ.

By expanding F
=F
(x 0 +cos θ, y 0 +sin θ, z 0 )in a Taylor series about = 0,one finds

F
(x 0 +cos θ, y 0 +sin θ, z 0 ) = F
(x 0 , y 0 , z 0 ) + dF


d

+

2

2!

d^2 F


d^2

+···,

where all the derivatives are evaluated at = 0. The circulation can be written as

I=

∫

C

©F
·d
r =μ 0 +^2 μ 1 +^3 μ 2 +···,