Curl: Difference between revisions

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imported>Paul Wormer
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imported>Paul Wormer
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In a general 3-dimensional orthogonal [[curvilinear coordinate system]] ''u''<sub>1</sub>,
In a general 3-dimensional orthogonal [[curvilinear coordinate system]] ''u''<sub>1</sub>,
''u''<sub>2</sub>, and ''u''<sub>3</sub>, characterized by the [[scale factors]] ''h''<sub>1</sub>,
''u''<sub>2</sub>, and ''u''<sub>3</sub>, characterized by the [[scale factors]] ''h''<sub>1</sub>,
''h''<sub>2</sub>, and ''h''<sub>3</sub>, (also known as Lamé factors, the diagonal elements of the diagonal [[g-tensor]])
''h''<sub>2</sub>, and ''h''<sub>3</sub>, (also known as Lamé factors, the square roots of the elements of the diagonal [[g-tensor]])
the curl takes the form of the following [[determinant]] (evaluate along the first row):
the curl takes the form of the following [[determinant]] (evaluate along the first row):
:<math>
:<math>
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\end{vmatrix},
\end{vmatrix},
</math>
</math>
<!--
 
==Definition through Stokes'theorem==
==Definition through Stokes' theorem==
[[Stokes' theorem]] is  
[[Stokes' theorem]] is  
:<math>
:<math>
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\oint_C \mathbf{F}\cdot d\mathbf{s},
\oint_C \mathbf{F}\cdot d\mathbf{s},
</math>
</math>
where d'''S''' is a vector of length the infinitesimal d''S'' and direction perpendicular to this surface. The intergal is over a surface ''S'' encircled by a contour ''C''. The right-hand side is an integral along the path ''C''. If we take ''S'' so small that the integrand of the integral on the left-hand side may be taken constant, the integral becomes
where d'''''S''''' is a vector of length the infinitesimal surface d''S'' and direction perpendicular to this surface. The integral is over a surface ''S'' encircled by a contour (closed non-intersecting path) ''C''. The right-hand side is an integral along ''C''. If we take ''S'' so small that the integrand of the integral on the left-hand side may be taken constant, the integral becomes
:<math>
(\boldsymbol{\nabla}\times \mathbf{F})\cdot\hat{\mathbf{n}}\; \Delta S
</math>
where <math>\hat{\mathbf{n}} </math> is a unit vector perpendicular to &Delta;''S''. The right-hand side is an integral over a small contour, say a small circle, and in total the curl may be written as
:<math>
:<math>
\mathbf{F}\cdot\hat{\mathbf{n}} \Delta S
(\boldsymbol{\nabla}\times \mathbf{F})\cdot\hat{\mathbf{n}} = \lim_{\Delta S \rightarrow 0} \frac{1}{\Delta S}\; \oint_C \mathbf{F}\cdot d\mathbf{s},
</math>
</math>
where <math>\hat{\mathbf{n}} </math> is a unit vector perpendicular to &Delta;''S''.
The line integral along the infinitesimally small circle ''C'' is the total "circulation" of '''F''' at the center of the circle. This leads to the following interpretation of the curl: It is a vector with a component oriented perpendicular to the plane of circulation. The perpendicular component has length equal to the circulation per unit surface.
-->
==External link==
[http://mathworld.wolfram.com/Curl.html MathWorld curl]

Revision as of 20:32, 15 April 2009

Given a 3-dimensional vector field F(r), the curl (also known as rotation) of F(r) is the differential vector operator nabla (symbol ) applied to F. The application of is in the form of a cross product:

where ex, ey, and ez are unit vectors along the axes of a Cartesian coordinate system of axes.

As any cross product the curl may be written in a few alternative ways.

As a determinant (evaluate along the first row):

As a vector-matrix-vector product

In terms of the antisymmetric Levi-Civita symbol εαβγ

(the component of the curl along the Cartesian α-axis).

Two important applications of the curl are (i) in Maxwell equations for electromagnetic fields and (ii) in the Helmholtz decomposition of arbitary vector fields.

From the Helmholtz decomposition follows that any curl-free vector field (also known as irrotational field) F(r), i.e., a vector field for which

can be written as minus the gradient of a scalar potential Φ

Orthogonal curvilinear coordinate systems

In a general 3-dimensional orthogonal curvilinear coordinate system u1, u2, and u3, characterized by the scale factors h1, h2, and h3, (also known as Lamé factors, the square roots of the elements of the diagonal g-tensor) the curl takes the form of the following determinant (evaluate along the first row):

For instance, in the case of spherical polar coordinates r, θ, and φ

the curl is

Definition through Stokes' theorem

Stokes' theorem is

where dS is a vector of length the infinitesimal surface dS and direction perpendicular to this surface. The integral is over a surface S encircled by a contour (closed non-intersecting path) C. The right-hand side is an integral along C. If we take S so small that the integrand of the integral on the left-hand side may be taken constant, the integral becomes

where is a unit vector perpendicular to ΔS. The right-hand side is an integral over a small contour, say a small circle, and in total the curl may be written as

The line integral along the infinitesimally small circle C is the total "circulation" of F at the center of the circle. This leads to the following interpretation of the curl: It is a vector with a component oriented perpendicular to the plane of circulation. The perpendicular component has length equal to the circulation per unit surface.

External link

MathWorld curl