Begin2.DVI

The curl F can be expressed by using the operator ∇in the determinant form

curl F =∇× F =

∣∣ ∣∣ ∣∣

ê 1 ê 2 ê 3 ∂ ∂x

∂ ∂y

∂ ∂z F 1 F 2 F 3

∣∣ ∣∣ ∣∣=ˆe^1 [

∂F 3 ∂y −

∂F 2 ∂z ]−eˆ^2 [

∂F 3 ∂x −

∂F 1 ∂z ] + eˆ^3 [

∂F 2 ∂x −

∂F 1 ∂y ] (8.38)

Example 8-9. Find the curlof the vector field

F=x^2 yê 1 + (x^2 +y^2 z)ê 2 + 4 xyz ê 3

Solution From the relation (8.38) one finds

curl F =

∣∣ ∣∣ ∣∣

ê 1 ê 2 ê 3 ∂ ∂x

∂ ∂y

∂ ∂z x^2 y x^2 +y^2 z 4 xyz

∣∣ ∣∣ ∣∣

curl F = (4xz −y^2 )ê 1 − 4 yz ê 2 + (2 x−x^2 )ê 3.

Physical Interpretation of Curl

The curlof a vector field is itself a vector field. If curl F = 0 at all points of a

region R, where F is defined, then the vector field F is called an irrotational vector

field , otherwise the vector field is called rotational.

The circulation

∫

C

©F·dr about a point P 0 can be written as

∫

C

©F ·dr =

∫

C

©F·drds ds =

∫

C

©F·ˆetds

where Cis a simple closed curve about the point P 0 enclosing an area. The quantity

F·eˆt, evaluated at a point on the curve C, represents the projection of the vector

F(x, y, z ), onto the unit tangent vector to the curve C. If the summation of these

tangential components around the simple closed curve is positive or negative, then

this indicates that there is a moment about the point P 0 which causes a rotation.

The circulation is a measure of the forces tending to produce a rotation about a given

point P 0 .The curl is the limit of the circulation divided by the area surrounding P 0

as the area tends toward zero. The curl can also be thought of as a measure of the

circulation density of the field or as a measure of the angular velocity produced by

the vector field.

Consider the two-dimensional velocity field V =V 0 ˆe 1 , 0 ≤y ≤h, where V 0

is constant, which is illustrated in figure 8-12(a). The velocity field V =V 0 ˆe 1 is

uniform, and to each point (x, y )there corresponds a constant velocity vector in the

ˆe 1 direction. The curlof this velocity field is zero since the derivative of a constant

is zero. The given velocity field is an example of an irrotational vector field.

Begin2.DVI

The curl F can be expressed by using the operator ∇in the determinant form

Example 8-9. Find the curlof the vector field

Solution From the relation (8.38) one finds

Physical Interpretation of Curl

The curlof a vector field is itself a vector field. If curl F = 0 at all points of a

region R, where F is defined, then the vector field F is called an irrotational vector

field , otherwise the vector field is called rotational.

The circulation

©F·dr about a point P 0 can be written as

where Cis a simple closed curve about the point P 0 enclosing an area. The quantity

F·eˆt, evaluated at a point on the curve C, represents the projection of the vector

F(x, y, z ), onto the unit tangent vector to the curve C. If the summation of these

tangential components around the simple closed curve is positive or negative, then

this indicates that there is a moment about the point P 0 which causes a rotation.

The circulation is a measure of the forces tending to produce a rotation about a given

point P 0 .The curl is the limit of the circulation divided by the area surrounding P 0

as the area tends toward zero. The curl can also be thought of as a measure of the

circulation density of the field or as a measure of the angular velocity produced by

Consider the two-dimensional velocity field V =V 0 ˆe 1 , 0 ≤y ≤h, where V 0

is constant, which is illustrated in figure 8-12(a). The velocity field V =V 0 ˆe 1 is

uniform, and to each point (x, y )there corresponds a constant velocity vector in the

ˆe 1 direction. The curlof this velocity field is zero since the derivative of a constant

is zero. The given velocity field is an example of an irrotational vector field.

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