In physics and mathematical analysis, Gauss's law gives the relation between the electric flux flowing out a closed surface and the electric charge enclosed in the surface.

Integral Form

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In its integral form, the law states:

$\backslash Phi\; =\; \backslash oint\_S\; \backslash mathbf\{E\}\; \backslash cdot\; d\backslash mathbf\{A\}$

= {1 \over \epsilon_o} \int_V \rho\ dV = \frac{Q_A}{\epsilon_o}

where $\backslash Phi$ is the electric flux, $\backslash mathbf\{E\}$ is the electric field, $d\backslash mathbf\{A\}$ is the area of a differential square on the closed surface S with an outward facing surface normal defining its direction, $Q\_\backslash mathrm\{A\}$ is the charge enclosed by the surface, $\backslash rho$ is the charge density at a point in $V$, $\backslash epsilon\_o$ is the permittivity of free space and $\backslash oint\_S$ is the integral over the surface S enclosing volume V.

For information and strategy on the application of Gauss's law see Gaussian surfaces.

Differential Form

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In differential form, the equation becomes:

$\backslash nabla\; \backslash cdot\; \backslash mathbf\{D\}\; =\; \backslash rho$

where $\backslash nabla$ is the del operator, representing divergence, D is the electric displacement field (in units of C/m²), and ρ is the free electric charge density (in units of C/m³), not including dipole charges bound in a material. The differential form derives in part from Gauss's divergence theorem.

And for linear materials, the equation becomes:

$\backslash nabla\; \backslash cdot\; \backslash epsilon\; \backslash mathbf\{E\}\; =\; \backslash rho$

where $\backslash epsilon$ is the electrical permittivity.

Coulomb's Law

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In the special case of a spherical surface with a central charge, the electric field is perpendicular to the surface, with the same magnitude at all points of it, giving the simpler expression:

$E=\backslash frac\{Q\}\{4\backslash pi\backslash epsilon\_0r^\{2\}\}$

where E is the electric field strength at radius r, Q is the enclosed charge, and ε₀ is the permitivity of free space. Thus the familiar inverse-square law dependence of the electric field in Coulomb's law follows from Gauss's law.

Gauss's law can be used to demonstrate that there is no electric field inside a Faraday cage with no electric charges. Gauss's law is the electrostatic equivalent of Ampère's law, which deals with magnetism. Both equations were later integrated into Maxwell's equations.

It was formulated by Carl Friedrich Gauss in 1835, but was not published until 1867. Because of the mathematical similarity, Gauss's law has application for other physical quantities governed by an inverse-square law such as gravitation or the intensity of radiation. See also divergence theorem.

Gravitational Analogue

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Since both gravity and electromagnetism propagate relative to the squared distance between two objects, we can relate the two using Gauss's Law by examining their respective vector fields $\backslash mathbf\{G\}$ and $\backslash mathbf\{E\}$, where

$\backslash mathbf\{G\}\; =\; -G\_\{c\}\; \backslash frac\{m\}\{r^2\}\backslash hat\{r\}$,

and

$\backslash mathbf\{E\}\; =\; \backslash frac\{1\}\{4\; \backslash pi\; \backslash epsilon\_\{0\}\}\; \backslash frac\{q\}\{r^2\}\backslash hat\{r\}$,

where $G\_\{c\}$ is the gravitational constant, $m$ is the mass of the point source, $r$ is the radius (distance) between the point source and another object, $\backslash epsilon\_\{0\}$ is the permittivity of free space, and $q$ is the charge of the electric point source.

In the same way that we evaluate the surface integral for electromagnetism to get the result $\backslash frac\{q\}\{\backslash epsilon\_\{0\}\}$, we can choose a proper Gaussian Surface to find an answer for the gravitational flux. For a point mass centered at the coordinate system origin, the most logical choice for our Gaussian surface is a sphere of radius $r$ centered at the origin.

We start with the integral form of Gauss's Law

$\backslash Phi\_\{G\}\; =\; \backslash oint\_S\; \backslash mathbf\{G\}\; \backslash cdot\; d\backslash mathbf\{A\}$.

An infinitesimal area element is just the area of the infinitesimal solid angle, which is defined as

$d\backslash mathbf\{A\}\; =\; r^\{2\}\; d\backslash Omega\; \backslash hat\{r\}$.

Our Gaussian Surface is wisely chosen since the vector normal to the surface is radial from the origin. With

$\backslash Phi\_\{G\}\; =\; \backslash oint\_S\; G(r)\; \backslash hat\{r\}\; \backslash cdot\; \backslash hat\{r\}\; r^\{2\}\; d\backslash Omega$,

we see the inner product of the two radial vectors is unity and that both the magnitude of our field, $\backslash mathbf\{G\}$, and the square of the distance between the surface and the point, $r^\{2\}$, remain constant over every element of the surface. This gives us the integral

$\backslash Phi\_\{G\}\; =\; G(r)\; r^\{2\}\; \backslash oint\_S\; d\backslash Omega$.

The remaining surface integral is just the surface area of our sphere ($4\; \backslash pi\; r^\{2\}$). If we combine this with our gravitational field equation from above, we have an expression for the gravitational flux of a point mass.

$\backslash Phi\_\{G\}\; =\; -\backslash frac\{G\_\{c\}m\}\{r^2\}\; 4\; \backslash pi\; r^\{2\}\; =\; -4\backslash pi\; G\_\{c\}m$

It is interesting to note that the gravitational flux, like its electromagnetic counterpart, does not depend on the radius of the sphere.

See also

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• Maxwell's equations
• Gaussian surface
• Carl Friedrich Gauss
• Divergence theorem
• Flux
• Method of image charges

External links

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• MISN-0-132 Gauss's Law for Spherical Symmetry (PDF file) by Peter Signell for Project PHYSNET.
• MISN-0-133 ''Gauss's Law Applied to Cylindrical and Planar Charge Distributions (PDF file) by Peter Signell for Project PHYSNET.

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