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In vector calculus, the curl is a vector operator that describes the infinitesimal rotation of a 3dimensional vector field. At every point in the field, the curl of that point is represented by a vector. The attributes of this vector (length and direction) characterize the rotation at that point.
The direction of the curl is the axis of rotation, as determined by the righthand rule, and the magnitude of the curl is the magnitude of rotation. If the vector field represents the flow velocity of a moving fluid, then the curl is the circulation density of the fluid. A vector field whose curl is zero is called irrotational. The curl is a form of differentiation for vector fields. The corresponding form of the fundamental theorem of calculus is Stokes' theorem, which relates the surface integral of the curl of a vector field to the line integral of the vector field around the boundary curve.
The alternative terminology rotor or rotational and alternative notations rot F and ∇ × F are often used (the former especially in many European countries, the latter, using the del operator and the cross product, is more used in other countries) for curl and curl F.
Unlike the gradient and divergence, curl does not generalize as simply to other dimensions; some generalizations are possible, but only in three dimensions is the geometrically defined curl of a vector field again a vector field. This is a similar phenomenon as in the 3 dimensional cross product, and the connection is reflected in the notation ∇ × for the curl.
The name "curl" was first suggested by James Clerk Maxwell in 1871^{[1]} but the concept was apparently first used in the construction of an optical field theory by James MacCullagh in 1839.^{[2]}
Definition
The components of
F at position
r, normal and tangent to a closed curve
C in a plane, enclosing a planar
vector area A =
An.
The curl of a vector field F, denoted by curl F, or ∇ × F, or rot F, at a point is defined in terms of its projection onto various lines through the point. If \scriptstyle\mathbf{\hat{n}} is any unit vector, the projection of the curl of F onto \scriptstyle\mathbf{\hat{n}} is defined to be the limiting value of a closed line integral in a plane orthogonal to \scriptstyle\mathbf{\hat{n}} as the path used in the integral becomes infinitesimally close to the point, divided by the area enclosed.
As such, the curl operator maps continuously differentiable functions f :
R^{3} →
R^{3} to continuous functions g :
R^{3} →
R^{3}. In fact, it maps
C^{k} functions in
R^{3} to
C^{k1} functions in
R^{3}.
Convention for vector orientation of the line integral
Implicitly, curl is defined by:^{[3]}^{[4]}

(\nabla \times \mathbf{F}) \cdot \mathbf{\hat{n}} \ \overset{\underset{\mathrm{def}}{}}{=} \lim_{A \to 0}\left( \frac{1}{A}\oint_{C} \mathbf{F} \cdot d\mathbf{r}\right)
where \scriptstyle\oint_{C} \mathbf{F} \cdot d\mathbf{r} is a line integral along the boundary of the area in question, and A is the magnitude of the area. If \scriptstyle\mathbf{\hat{\nu}} is an outward pointing inplane normal, whereas \scriptstyle\mathbf{\hat{n}} is the unit vector perpendicular to the plane (see caption at right), then the orientation of C is chosen so that a tangent vector \scriptstyle\mathbf{\hat{\omega}} to C is positively oriented if and only if \scriptstyle\{\mathbf{\hat{n}},\mathbf{\hat{\nu}},\mathbf{\hat{\omega}}\} forms a positively oriented basis for R^{3} (righthand rule).
The above formula means that the curl of a vector field is defined as the infinitesimal area density of the circulation of that field. To this definition fit naturally


({\rm curl}\,\mathbf F)\,_1=\frac{1}{h_2h_3}\left (\frac{\partial (h_3F_3)}{\partial u_2}\frac{\partial (h_2F_2)}{\partial u_3}\right )\,,


({\rm curl}\,\mathbf F)\,_2=\frac{1}{h_3h_1}\left (\frac{\partial (h_1F_1)}{\partial u_3}\frac{\partial (h_3F_3)}{\partial u_1}\right )\,,


({\rm curl}\,\mathbf F)\,_3=\frac{1}{h_1h_2}\left (\frac{\partial (h_2F_2)}{\partial u_1}\frac{\partial (h_1F_1)}{\partial u_2}\right )\,.
Note that the equation for each component, ({\rm curl}\,\mathbf F)\,_k can be obtained by exchanging each occurrence of a subscript _{1, 2, 3} in cyclic permutation: 1→2, 2→3, and 3→1 (where the subscripts represent the relevant indices).
If (x_{1}, x_{2}, x_{3}) are the Cartesian coordinates and (u_{1},u_{2},u_{3}) are the orthogonal coordinates, then

h_i = \sqrt{\sum \limits_{j = 1}^{3}\left (\frac{\partial x_j}{\partial u_i}\right )^2}
is the length of the coordinate vector corresponding to u_{i}. The remaining two components of curl result from cyclic permutation of indices: 3,1,2 → 1,2,3 → 2,3,1.
Intuitive interpretation
Suppose the vector field describes the velocity field of a fluid flow (such as a large tank of liquid or gas) and a small ball is located within the fluid or gas (the centre of the ball being fixed at a certain point). If the ball has a rough surface, the fluid flowing past it will make it rotate. The rotation axis (oriented according to the right hand rule) points in the direction of the curl of the field at the centre of the ball, and the angular speed of the rotation is half the magnitude of the curl at this point.^{[5]}
Usage
In practice, the above definition is rarely used because in virtually all cases, the curl operator can be applied using some set of curvilinear coordinates, for which simpler representations have been derived.
The notation ∇ × F has its origins in the similarities to the 3 dimensional cross product, and it is useful as a mnemonic in Cartesian coordinates if ∇ is taken as a vector differential operator del. Such notation involving operators is common in physics and algebra. However, in certain coordinate systems, such as polartoroidal coordinates (common in plasma physics), using the notation ∇ × F will yield an incorrect result.
Expanded in Cartesian coordinates (see Del in cylindrical and spherical coordinates for spherical and cylindrical coordinate representations), ∇ × F is, for F composed of [F_{x}, F_{y}, F_{z}]:

\begin{vmatrix} \mathbf{i} & \mathbf{j} & \mathbf{k} \\ \\ {\frac{\partial}{\partial x}} & {\frac{\partial}{\partial y}} & {\frac{\partial}{\partial z}} \\ \\ F_x & F_y & F_z \end{vmatrix}
where i, j, and k are the unit vectors for the x, y, and zaxes, respectively. This expands as follows:^{[6]}

\left(\frac{\partial F_z}{\partial y}  \frac{\partial F_y}{\partial z}\right) \mathbf{i} + \left(\frac{\partial F_x}{\partial z}  \frac{\partial F_z}{\partial x}\right) \mathbf{j} + \left(\frac{\partial F_y}{\partial x}  \frac{\partial F_x}{\partial y}\right) \mathbf{k}
Although expressed in terms of coordinates, the result is invariant under proper rotations of the coordinate axes but the result inverts under reflection.
In a general coordinate system, the curl is given by^{[7]}

(\nabla \times \mathbf{F} )^k = \epsilon^{k\ell m} \partial_\ell F_m
where ε denotes the LeviCivita symbol, the metric tensor is used to lower the index on F, and the Einstein summation convention implies that repeated indices are summed over. Equivalently,

(\nabla \times \mathbf{F} ) = \boldsymbol{e}_k\epsilon^{k\ell m} \partial_\ell F_m
where e_{k} are the coordinate vector fields. Equivalently, using the exterior derivative, the curl can be expressed as:

\nabla \times \mathbf{F} = \left[ \star \left( {\mathbf d} F^\flat \right) \right]^\sharp
Here \scriptstyle\flat and \scriptstyle\sharp are the musical isomorphisms, and \scriptstyle\star is the Hodge dual. This formula shows how to calculate the curl of F in any coordinate system, and how to extend the curl to any oriented threedimensional Riemannian manifold. Since this depends on a choice of orientation, curl is a chiral operation. In other words, if the orientation is reversed, then the direction of the curl is also reversed.
Examples
A simple vector field
Take the vector field, which depends on x and y linearly:

\mathbf{F}(x,y,z)=y\boldsymbol{\hat{x}}x\boldsymbol{\hat{y}}.
Its plot looks like this:
Simply by visual inspection, we can see that the field is rotating. If we place a paddle wheel anywhere, we see immediately its tendency to rotate clockwise. Using the righthand rule, we expect the curl to be into the page. If we are to keep a righthanded coordinate system, into the page will be in the negative z direction. The lack of x and y directions is analogous to the cross product operation.
If we calculate the curl:

\nabla \times \mathbf{F} =0\boldsymbol{\hat{x}}+0\boldsymbol{\hat{y}}+ \left(x) {\frac{\partial}{\partial y}} y\right]\boldsymbol{\hat{z}}=2\boldsymbol{\hat{z}}
Which is indeed in the negative z direction, as expected. In this case, the curl is actually a constant, irrespective of position. The "amount" of rotation in the above vector field is the same at any point (x, y). Plotting the curl of F is not very interesting:
A more involved example
Suppose we now consider a slightly more complicated vector field:

\mathbf{F}(x,y,z)=x^2\boldsymbol{\hat{y}}.
Its plot:
We might not see any rotation initially, but if we closely look at the right, we see a larger field at, say, x=4 than at x=3. Intuitively, if we placed a small paddle wheel there, the larger "current" on its right side would cause the paddlewheel to rotate clockwise, which corresponds to a curl in the negative z direction. By contrast, if we look at a point on the left and placed a small paddle wheel there, the larger "current" on its left side would cause the paddlewheel to rotate counterclockwise, which corresponds to a curl in the positive z direction. Let's check out our guess by doing the math:

{\nabla} \times \mathbf{F} =0\boldsymbol{\hat{x}}+0\boldsymbol{\hat{y}}+ {\frac{\partial}{\partial x}}(x^2) \boldsymbol{\hat{z}}=2x\boldsymbol{\hat{z}}.
Indeed the curl is in the positive z direction for negative x and in the negative z direction for positive x, as expected. Since this curl is not the same at every point, its plot is a bit more interesting:
We note that the plot of this curl has no dependence on y or z (as it shouldn't) and is in the negative z direction for positive x and in the positive z direction for negative x.
Identities
In general curvilinear coordinates (not only in Cartesian coordinates), the curl of a cross product of vector fields v and F can be shown to be

\nabla \times \left( \mathbf{v \times F} \right) = \left[ \left( \mathbf{ \nabla \cdot F } \right) + \mathbf{F \cdot \nabla} \right] \mathbf{v} \left[ \left( \mathbf{ \nabla \cdot v } \right) + \mathbf{v \cdot \nabla} \right] \mathbf{F} \ .
Interchanging the vector field v and ∇ operator, we arrive at the cross product of a vector field with curl of a vector field:

\mathbf{v \ \times } \left( \mathbf{ \nabla \times F} \right) =\nabla_F \left( \mathbf{v \cdot F } \right)  \left( \mathbf{v \cdot \nabla } \right) \mathbf{ F} \ ,
using the Feynman subscript notation, ∇_{F}, which operates only on the vector field F.
Another example is the curl of a curl of a vector field. It can be shown that in general coordinates

\nabla \times \left( \mathbf{\nabla \times F} \right) = \mathbf{\nabla} (\mathbf{\nabla \cdot F})  \nabla^2 \mathbf{F} \ ,
and this identity defines the vector Laplacian of F, symbolized as ∇^{2}F.
The curl of the gradient of any scalar field φ is always the zero vector field

\nabla \times ( \nabla \phi ) = \boldsymbol{0}
which follows from the antisymmetry in the definition of the curl, and the symmetry of second derivatives.
If φ is a scalar valued function and F is a vector field, then

\nabla \times ( \varphi \mathbf{F}) = \nabla \varphi \times \mathbf{F} + \varphi \nabla \times \mathbf{F}
Descriptive examples

In a vector field describing the linear velocities of each part of a rotating disk, the curl has the same value at all points.

Of the four Maxwell's equations, two—Faraday's law and Ampère's law—can be compactly expressed using curl. Faraday's law states that the curl of an electric field is equal to the opposite of the time rate of change of the magnetic field, while Ampère's law relates the curl of the magnetic field to the current and rate of change of the electric field.
Generalizations
The vector calculus operations of grad, curl, and div are most easily generalized and understood in the context of differential forms, which involves a number of steps. In a nutshell, they correspond to the derivatives of 0forms, 1forms, and 2forms, respectively. The geometric interpretation of curl as rotation corresponds to identifying bivectors (2vectors) in 3 dimensions with the special orthogonal Lie algebra so(3) of infinitesimal rotations (in coordinates, skewsymmetric 3 × 3 matrices), while representing rotations by vectors corresponds to identifying 1vectors (equivalently, 2vectors) and so(3), these all being 3dimensional spaces.
Differential forms
In 3 dimensions, a differential 0form is simply a function f(x, y, z); a differential 1form is the following expression: a_1\,dx + a_2\,dy + a_3\,dz; a differential 2form is the formal sum: a_{12}\,dx\wedge dy + a_{13}\,dx\wedge dz + a_{23}\,dy\wedge dz; and a differential 3form is defined by a single term: a_{123}\,dx\wedge dy\wedge dz. (Here the acoefficients are real functions; the "wedge products", e.g. dx\wedge dy, can be interpreted as some kind of oriented area elements, dx\wedge dy=dy\wedge dx, etc.) The exterior derivative of a kform in R^{3} is defined as the (k+1)form from above (and in R^{n} if, e.g.,

\omega^{(k)}=\sum_{i_1
then the exterior derivative d leads to

d\,\omega^{(k)}=\sum_{j=1;\, i_1<...
The exterior derivative of a 1form is therefore a 2form, and that of a 2form is a 3form. On the other hand, because of the interchangeability of mixed derivatives, e.g. because of

\frac{\partial^2}{\partial x\partial y}=\frac{\partial^2}{\partial y\partial x},
the twofold application of the exterior derivative leads to 0.
Thus, denoting the space of kforms by \Omega^k(\mathbf{R}^3) and the exterior derivative by d one gets a sequence:

0 \overset{d}{\to} \Omega^0(\mathbf{R}^3) \overset{d}{\to} \Omega^1(\mathbf{R}^3) \overset{d}{\to} \Omega^2(\mathbf{R}^3)\overset{d}{\to} \Omega^3(\mathbf{R}^3)\overset{d}{\to} 0.
Here \Omega^k(\mathbf{R}^n) is the space of sections of the exterior algebra \Lambda^k(\mathbf{R}^n) vector bundle over R^{n}, whose dimension is the binomial coefficient \textstyle{\binom{n}{k}}; note that \Omega^k(\mathbf{R}^3) = 0 for k > 3 or k < 0. Writing only dimensions, one obtains a row of Pascal's triangle:

0 → 1 → 3 → 3 → 1 → 0;
the 1dimensional fibers correspond to functions, and the 3dimensional fibers to vector fields, as described below. Note that modulo suitable identifications, the three nontrivial occurrences of the exterior derivative correspond to grad, curl, and div.
Differential forms and the differential can be defined on any Euclidean space, or indeed any manifold, without any notion of a Riemannian metric. On a Riemannian manifold, or more generally pseudoRiemannian manifold, kforms can be identified with kvector fields (kforms are kcovector fields, and a pseudoRiemannian metric gives an isomorphism between vectors and covectors), and on an oriented vector space with a nondegenerate form (an isomorphism between vectors and covectors), there is an isomorphism between kvectors and (n−k)vectors; in particular on (the tangent space of) an oriented pseudoRiemannian manifold. Thus on an oriented pseudoRiemannian manifold, one can interchange kforms, kvector fields, (n−k)forms, and (n−k)vector fields; this is known as Hodge duality. Concretely, on R^{3} this is given by:

1forms and 1vector fields: the 1form a_x\,dx + a_y\,dy + a_z\,dz corresponds to the vector field (a_x, a_y, a_z).

1forms and 2forms: one replaces dx by the "dual" quantity dy \wedge dz (i.e., omit dx), and likewise, taking care of orientation: dy corresponds to dz \wedge dx = dx \wedge dz, and dz corresponds to dx \wedge dy. Thus the form a_x\,dx + a_y\,dy + a_z\,dz corresponds to the "dual form" a_z\,dx\wedge dy + a_y\,dz\wedge dx + a_x\,dy\wedge dz.
Thus, identifying 0forms and 3forms with functions, and 1forms and 2forms with vector fields:

grad takes a function (0form) to a vector field (1form);

curl takes a vector field (1form) to a vector field (2form);

div takes a vector field (2form) to a function (3form)
On the other hand the fact that d^{2} = 0 corresponds to the identities curl grad f = 0 and \mathrm{div\,\, curl\,\,}\vec v\,=0 for any function f or vector field \vec v.
Grad and div generalize to all oriented pseudoRiemannian manifolds, with the same geometric interpretation, because the spaces of 0forms and nforms is always (fiberwise) 1dimensional and can be identified with scalar functions, while the spaces of 1forms and (n−1)forms are always fiberwise ndimensional and can be identified with vector fields.
Curl does not generalize in this way to 4 or more dimensions (or down to 2 or fewer dimensions); in 4 dimensions the dimensions are

0 → 1 → 4 → 6 → 4 → 1 → 0;
so the curl of a 1vector field (fiberwise 4dimensional) is a 2vector field, which is fiberwise 6dimensional, one has

\omega^{(2)}=\sum_{i
which yields a sum of six independent terms, and cannot be identified with a 1vector field. Nor can one meaningfully go from a 1vector field to a 2vector field to a 3vector field (4 → 6 → 4), as taking the differential twice yields zero (d^{2} = 0). Thus there is no curl function from vector fields to vector fields in other dimensions arising in this way.
However, one can define a curl of a vector field as a 2vector field in general, as described below.
Curl geometrically
2vectors correspond to the exterior power Λ^{2}V; in the presence of an inner product, in coordinates these are the skewsymmetric matrices, which are geometrically considered as the special orthogonal Lie algebra so(V) of infinitesimal rotations. This has \textstyle{\binom{n}{2}=\frac{1}{2}n(n1)} dimensions, and allows one to interpret the differential of a 1vector field as its infinitesimal rotations. Only in 3 dimensions (or trivially in 0 dimensions) is \textstyle{n=\frac{1}{2}n(n1)}, which is the most elegant and common case. In 2 dimensions the curl of a vector field is not a vector field but a function, as 2dimensional rotations are given by an angle (a scalar  an orientation is required to choose whether one counts clockwise or counterclockwise rotations as positive); note that this is not the div, but is rather perpendicular to it. In 3 dimensions the curl of a vector field is a vector field as is familiar (in 1 and 0 dimensions the curl of a vector field is 0, because there are no nontrivial 2vectors), while in 4 dimensions the curl of a vector field is, geometrically, at each point an element of the 6dimensional Lie algebra so(4).
Note also that the curl of a 3dimensional vector field which only depends on 2 coordinates (say x, y) is simply a vertical vector field (in the z direction) whose magnitude is the curl of the 2dimensional vector field, as in the examples on this page.
Considering curl as a 2vector field (an antisymmetric 2tensor) has been used to generalize vector calculus and associated physics to higher dimensions.^{[8]}
See also
Notes

^ Proceedings of the London Mathematical Society, March 9th, 1871

^ Collected works of James MacCullagh

^ Mathematical methods for physics and engineering, K.F. Riley, M.P. Hobson, S.J. Bence, Cambridge University Press, 2010, ISBN 9780521861533

^ Vector Analysis (2nd Edition), M.R. Spiegel, S. Lipschutz, D. Spellman, Schaum’s Outlines, McGraw Hill (USA), 2009, ISBN 9780071615457

^

^ Arfken, p. 43.

^ Weisstein, Eric W., "Curl", MathWorld.

^ Generalizing Cross Products and Maxwell's Equations to Universal Extra Dimensions, A.W. McDavid, C.D. McMullen, 2006
References

Arfken, George B. and Hans J. Weber. Mathematical Methods For Physicists, Academic Press; 6 edition (June 21, 2005). ISBN 9780120598762.

External links


The idea of curl of a vector field

Curl BetterExplained
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