Vector Laplacian

In mathematics and physics, the vector Laplace operator, denoted by $scriptstyle
abla^2$ , named after Pierre-Simon Laplace, is a differential operator defined over a vector field. The vector Laplacian is similar to the scalar Laplacian. Whereas the scalar Laplacian applies to scalar field and returns a scalar quantity, the vector Laplacian applies to the vector fields and returns a vector quantity.

Definition

The vector Laplacian of a vector field $mathbf{A}$ is defined as

: $abla^2 mathbf{A} =
abla(
abla cdot mathbf{A}) -
abla imes (
abla imes mathbf{A})$

In Cartesian coordinates, this reduces to the much simpler form (see proof)

: $abla^2 mathbf{A} = (
abla^2 A_x,
abla^2 A_y,
abla^2 A_z)$

where $A_x$ , $A_y$ , and $A_z$ are the components of $mathbf{A}$ .

For expressions of the vector Laplacian in other coordinate systems see Nabla in cylindrical and spherical coordinates.

Generalization

The Laplacian of any tensor field $T$ ("tensor" includes scalar and vector) is defined as the divergence of the gradient of the tensor:

: $abla^2 T =
abla cdot (
abla T)$

For the special case where $T$ is a scalar (a tensor of rank zero), the Laplacian takes on the familiar form.

If $T$ is a vector, the gradient is a covariant derivative which results in a tensor of second rank, and the divergence of this is again a vector (a tensor of first rank). The formula for the vector Laplacian above may be used to avoid tensor math and may be shown to be equivalent to the divergence of the gradient of the vector.

Use in physics

An example of the usage of the vector Laplacian is the Navier-Stokes equations for a Newtonian incompressible flow:

: $ho left(frac{partial mathbf{v{partial t}+ ( mathbf{v} cdot
abla ) mathbf{v}
ight)=
ho mathbf{f}-
abla p +muleft(
abla ^2 mathbf{v}
ight)$

where the term with the vector Laplacian of the velocity field $muleft(
abla ^2 mathbf{v}
ight)$ represents the viscous stresses in the fluid.

Another example is the wave equation for the electric field that can be derived fromthe Maxwell equations in the absence of charges and currents:

:: $abla^2 mathbf{E} - mu_0 epsilon_0 frac{partial^2 mathbf{E{partial t^2} = 0.$

Previous equation can be written also as:

:: $Box, mathbf{E} = 0,$ where :: $Box=frac{1}{c^2} frac{partial^2}{partial t^2}-
abla^2,$ is the D'Alembertian

ee also

*Vector Laplacian/Proofs

References

*cite web | url = http://mathworld.wolfram.com/VectorLaplacian.html | title = Vector Laplacian
author = MathWorld

Wikimedia Foundation. 2010.

Игры ⚽ Нужна курсовая?

Look at other dictionaries:

Vector Laplacian/Proofs — The following is the proof that: abla ^2 left( {mathbf{u ight) = abla left( { abla cdot{mathbf{u} ight) abla imes left( { abla imes {mathbf{u} ight) = leftlangle { abla ^2 u x , abla ^2 u y , abla ^2 u z } ight angle. This is a proof in Cartesian … Wikipedia
Vector calculus — Topics in Calculus Fundamental theorem Limits of functions Continuity Mean value theorem Differential calculus Derivative Change of variables Implicit differentiation Taylor s theorem Related rates … Wikipedia
Laplacian operators in differential geometry — In differential geometry there are a number of second order, linear, elliptic differential operators bearing the name Laplacian. This article provides an overview of some of them. Connection Laplacian The connection Laplacian is a differential… … Wikipedia
Laplacian vector field — In vector calculus, a Laplacian vector field is a vector field which is both irrotational and incompressible. If the field is denoted as v, then it is described by the following differential equations:: abla imes mathbf{v} = 0, : abla cdot… … Wikipedia
Vector operator — A vector operator is a type of differential operator used in vector calculus. Vector operators are defined in terms of del, and include the gradient, divergence, and curl:: operatorname{grad} equiv abla : operatorname{div} equiv abla cdot :… … Wikipedia
Vector calculus identities — The following identities are important in vector calculus:ingle operators (summary)This section explicitly lists what some symbols mean for clarity.DivergenceDivergence of a vector fieldFor a vector field mathbf{v} , divergence is generally… … Wikipedia
Vector fields in cylindrical and spherical coordinates — Cylindrical coordinate system = Vector fields Vectors are defined in cylindrical coordinates by (ρ,φ,z), where * ρ is the length of the vector projected onto the X Y plane, * φ is the angle of the projected vector with the positive X axis (0 ≤ φ… … Wikipedia
Conservative vector field — In vector calculus a conservative vector field is a vector field which is the gradient of a function, known in this context as a scalar potential. Conservative vector fields have the property that the line integral from one point to another is… … Wikipedia
Lamellar vector field — In vector analysis and in fluid dynamics, a lamellar vector field is a vector field with no rotational component. That is, if the field is denoted as v, then : abla imes mathbf{v} = 0 .A lamellar field is practically synonymous with an… … Wikipedia
Del — For other uses, see Del (disambiguation). ∇ Del operator, represented by the nabla symbol In vector calculus, del is a vector differential operator, usually represented by the nabla symbol . When applied to a function defined on a one dimensional … Wikipedia

Academic Dictionaries and Encyclopedias

Vector Laplacian

Look at other dictionaries:

Share the article and excerpts

Academic Dictionaries and Encyclopedias

Wikipedia

Vector Laplacian

Look at other dictionaries:

Share the article and excerpts

Direct link