Gaussian surface

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A Gaussian surface is a closed surface in three-dimensional space through which the flux of a vector field is calculated; usually the gravitational field, electric field, or magnetic field.^[1] It is an arbitrary closed surface Template:Math (the boundary of a 3-dimensional region Template:Mvar) used in conjunction with Gauss's law for the corresponding field (Gauss's law, Gauss's law for magnetism, or Gauss's law for gravity) by performing a surface integral, in order to calculate the total amount of the source quantity enclosed; e.g., amount of gravitational mass as the source of the gravitational field or amount of electric charge as the source of the electrostatic field, or vice versa: calculate the fields for the source distribution.

For concreteness, the electric field is considered in this article, as this is the most frequent type of field the surface concept is used for.

Gaussian surfaces are usually carefully chosen to exploit symmetries of a situation to simplify the calculation of the surface integral. If the Gaussian surface is chosen such that for every point on the surface the component of the electric field along the normal vector is constant, then the calculation will not require difficult integration as the constants which arise can be taken out of the integral. It is defined as the closed surface in three dimensional space by which the flux of vector field be calculated.

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File:SurfacesWithAndWithoutBoundary.svg

Most calculations using Gaussian surfaces begin by implementing Gauss's law (for electricity):^[2]

Template:Oiint

Thereby Template:Math is the electrical charge enclosed by the Gaussian surface.

This is Gauss's law, combining both the divergence theorem and Coulomb's law.

A spherical Gaussian surface is used when finding the electric field or the flux produced by any of the following:^[3]

• a point charge
• a uniformly distributed spherical shell of charge
• any other charge distribution with spherical symmetry

The spherical Gaussian surface is chosen so that it is concentric with the charge distribution.

As an example, consider a charged spherical shell Template:Mvar of negligible thickness, with a uniformly distributed charge Template:Mvar and radius Template:Mvar. We can use Gauss's law to find the magnitude of the resultant electric field Template:Mvar at a distance Template:Mvar from the center of the charged shell. It is immediately apparent that for a spherical Gaussian surface of radius Template:Math the enclosed charge is zero: hence the net flux is zero and the magnitude of the electric field on the Gaussian surface is also 0 (by letting Template:Math in Gauss's law, where Template:Math is the charge enclosed by the Gaussian surface).

With the same example, using a larger Gaussian surface outside the shell where Template:Math, Gauss's law will produce a non-zero electric field. This is determined as follows.

The flux out of the spherical surface Template:Mvar is:

Template:Oiint

The surface area of the sphere of radius Template:Mvar is $${\displaystyle \underset{S}{\iint }dA=4\pi r^2}$$ which implies $${\displaystyle {\mathrm{\Phi }}_E=E4\pi r^2}$$

By Gauss's law the flux is also $${\displaystyle {\mathrm{\Phi }}_E=\frac{Q_A}{{\epsilon }_0}}$$ finally equating the expression for Template:Math gives the magnitude of the Template:Math-field at position Template:Mvar: $${\displaystyle E4\pi r^2=\frac{Q_A}{{\epsilon }_0}\Rightarrow E=\frac{Q_A}{4\pi {\epsilon }_0{r}^2}.}$$

This non-trivial result shows that any spherical distribution of charge acts as a point charge when observed from the outside of the charge distribution; this is in fact a verification of Coulomb's law. And, as mentioned, any exterior charges do not count.

A cylindrical Gaussian surface is used when finding the electric field or the flux produced by any of the following:^[3]

• an infinitely long line of uniform charge
• an infinite plane of uniform charge
• an infinitely long cylinder of uniform charge

As example "field near infinite line charge" is given below;

Consider a point P at a distance Template:Mvar from an infinite line charge having charge density (charge per unit length) λ. Imagine a closed surface in the form of cylinder whose axis of rotation is the line charge. If Template:Mvar is the length of the cylinder, then the charge enclosed in the cylinder is $${\displaystyle q=\lambda h,}$$ where Template:Mvar is the charge enclosed in the Gaussian surface. There are three surfaces a, b and c as shown in the figure. The differential vector area is Template:Math, on each surface a, b and c.

File:Gaussian surface.jpg

The flux passing consists of the three contributions:

Template:Oiint

For surfaces a and b, Template:Math and Template:Math will be perpendicular. For surface c, Template:Math and Template:Math will be parallel, as shown in the figure.

$${\displaystyle \begin{array}{cc}{\mathrm{\Phi }}_E& =\underset{a}{\iint }EdA\cos 90^{\circ }+\underset{b}{\iint }EdA\cos 90^{\circ }+\underset{c}{\iint }EdA\cos 0^{\circ }\\ & =E\underset{c}{\iint }dA\end{array}}$$

The surface area of the cylinder is $${\displaystyle \underset{c}{\iint }dA=2\pi rh}$$ which implies $${\displaystyle {\mathrm{\Phi }}_E=E2\pi rh.}$$

By Gauss's law $${\displaystyle {\mathrm{\Phi }}_E=\frac{q}{{\epsilon }_0}}$$ equating for Template:Math yields $${\displaystyle E2\pi rh=\frac{\lambda h}{{\epsilon }_0}\Rightarrow E=\frac{\lambda }{2\pi {\epsilon }_{0}r}}$$

This surface is most often used to determine the electric field due to an infinite sheet of charge with uniform charge density, or a slab of charge with some finite thickness. The pillbox has a cylindrical shape, and can be thought of as consisting of three components: the disk at one end of the cylinder with area Template:Math, the disk at the other end with equal area, and the side of the cylinder. The sum of the electric flux through each component of the surface is proportional to the enclosed charge of the pillbox, as dictated by Gauss's Law. Because the field close to the sheet can be approximated as constant, the pillbox is oriented in a way so that the field lines penetrate the disks at the ends of the field at a perpendicular angle and the side of the cylinder are parallel to the field lines.

• Area
• Surface area
• Vector calculus
• Integration
• Divergence theorem
• Faraday cage
• Field theory
• Field line

Template:Reflist

• Template:Cite book
• Template:Cite book

• Electromagnetism (2nd Edition), I.S. Grant, W.R. Phillips, Manchester Physics, John Wiley & Sons, 2008, Template:ISBN

• Fields Template:Webarchive - a chapter from an online textbook

Template:Carl Friedrich Gauss