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Gauss’s law

The flux Φ of the electric field E through any closed surface S (a Gaussian surface) is equal to the net charge enclosed ( q enc ) divided by the permittivity of free space ( ε 0 ) :

Φ = S E · n ^ d A = q enc ε 0 .

To use Gauss’s law effectively, you must have a clear understanding of what each term in the equation represents. The field E is the total electric field at every point on the Gaussian surface. This total field includes contributions from charges both inside and outside the Gaussian surface. However, q enc is just the charge inside the Gaussian surface. Finally, the Gaussian surface is any closed surface in space. That surface can coincide with the actual surface of a conductor, or it can be an imaginary geometric surface. The only requirement imposed on a Gaussian surface is that it be closed ( [link] ).

Figure shows a bottle that looks like an upside down flask whose neck is elongated, bent upward, twisted, taken inside the bottle and joined with its base, thus having only one surface.
A Klein bottle partially filled with a liquid. Could the Klein bottle be used as a Gaussian surface?

Electric flux through gaussian surfaces

Calculate the electric flux through each Gaussian surface shown in [link] .

Figures a through d show irregular shapes and figure e shows a cube. Figure a has a charge inside the shape labeled plus 2.0 mu C. Figure b has a charge inside the shape labeled minus 2.0 mu C. Figure c has a charge inside the shape labeled plus 2.0 mu C and two charges outside labeled plus 4 mu C and minus 2.0 mu C. Figure d has three charges inside the shape labeled minus 1.0 mu C, minus 4.0 mu C and plus 6.0 mu C and two charges outside the shape labeled minus 5.0 mu C and plus 4.0 mu C. Figure e has three charges inside labeled plus 4.0 mu C, plus 6.0 mu C and minus 10.0 mu C and two charges outside the cube labeled plus 5.0 mu C and 3.0 mu C.
Various Gaussian surfaces and charges.

Strategy

From Gauss’s law, the flux through each surface is given by q enc / ε 0 , where q enc is the charge enclosed by that surface.

Solution

For the surfaces and charges shown, we find

  1. Φ = 2.0 μ C ε 0 = 2.3 × 10 5 N · m 2 /C .
  2. Φ = −2.0 μ C ε 0 = −2.3 × 10 5 N · m 2 /C .
  3. Φ = 2.0 μ C ε 0 = 2.3 × 10 5 N · m 2 /C .
  4. Φ = −4.0 μ C + 6.0 μ C 1.0 μ C ε 0 = 1.1 × 10 5 N · m 2 /C .
  5. Φ = 4.0 μ C + 6.0 μ C 10.0 μ C ε 0 = 0 .

Significance

In the special case of a closed surface, the flux calculations become a sum of charges. In the next section, this will allow us to work with more complex systems.

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Check Your Understanding Calculate the electric flux through the closed cubical surface for each charge distribution shown in [link] .

Figures a through d show a cuboid with one corner at the origin of the coordinate axes. In figure a, there is a charge plus 3.0 mu C on the surface parallel to the yz plane. In figure b, there is a charge minus 3.0 mu C on the surface parallel to the yz plane. In figure c, there is a charge plus 3.0 mu C on the surface parallel to the yz plane, a charge minus 3.0 mu C on the y axis outside the shape and a charge plus 6.0 mu C outside the shape. In figure d, there is a charge minus 3.0 mu C on the y axis outside the shape and charges plus 3.0 mu C and plus 6.0 mu C outside the shape.
A cubical Gaussian surface with various charge distributions.

a. 3.4 × 10 5 N · m 2 /C; b. −3.4 × 10 5 N · m 2 /C; c. 3.4 × 10 5 N · m 2 /C; d. 0

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Use this simulation to adjust the magnitude of the charge and the radius of the Gaussian surface around it. See how this affects the total flux and the magnitude of the electric field at the Gaussian surface.

Summary

  • Gauss’s law relates the electric flux through a closed surface to the net charge within that surface,
    Φ = S E · n ^ d A = q enc ε 0 ,

    where q enc is the total charge inside the Gaussian surface S .
  • All surfaces that include the same amount of charge have the same number of field lines crossing it, regardless of the shape or size of the surface, as long as the surfaces enclose the same amount of charge.

Conceptual questions

Two concentric spherical surfaces enclose a point charge q . The radius of the outer sphere is twice that of the inner one. Compare the electric fluxes crossing the two surfaces.

Since the electric field vector has a 1 r 2 dependence, the fluxes are the same since A = 4 π r 2 .

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Compare the electric flux through the surface of a cube of side length a that has a charge q at its center to the flux through a spherical surface of radius a with a charge q at its center.

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(a) If the electric flux through a closed surface is zero, is the electric field necessarily zero at all points on the surface? (b) What is the net charge inside the surface?

a. no; b. zero

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Discuss how Gauss’s law would be affected if the electric field of a point charge did not vary as 1 / r 2 .

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Discuss the similarities and differences between the gravitational field of a point mass m and the electric field of a point charge q .

Both fields vary as 1 r 2 . Because the gravitational constant is so much smaller than 1 4 π ε 0 , the gravitational field is orders of magnitude weaker than the electric field.

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Discuss whether Gauss’s law can be applied to other forces, and if so, which ones.

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Is the term E in Gauss’s law the electric field produced by just the charge inside the Gaussian surface?

No, it is produced by all charges both inside and outside the Gaussian surface.

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Reformulate Gauss’s law by choosing the unit normal of the Gaussian surface to be the one directed inward.

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Problems

Determine the electric flux through each surface whose cross-section is shown below.

Figure shows an irregular shape S1. Within it are four irregular shapes labeled S2, S3, S4 and S6 and a quadrilateral labeled S5. All these overlap with one or more of each other. A charge minus 2q is shown in the overlap region of S1, S2 and S4. A charge minus 2q is shown in the overlap region of S1, S4 and S5. A charge plus q is shown in the overlap region of S1 and S3. A charge plus 3q is shown in the overlap region of S1 and S6.
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Find the electric flux through the closed surface whose cross-sections are shown below.

Figure a shows an irregular shape with a positive charge inside it labeled 3 into 10 to the power minus 8 C. There is a negative charge outside it, labeled minus 2 into 10 to the power 8 C. Figure b shows an irregular shape with three charges outside it. These are plus 4 into 10 to the power minus 6 C, plus 5 into 10 to the power minus 6 C and minus three into 10 to the power minus 6 C. Figure c shows a square with the length of each side equal to a. There is a charge minus 2 into 10 to the power minus 6 C within it. Figure d shows a shaded strip with plus signs near the inside edges. It is labeled conductor. An arrow points outward from either end of the strip. These arrows are labeled infinity. A small rectangle is attached to one side of the strip, covering one plus sign. It is labeled end cap of area, 4 into 10 to the power minus 4 m squared. The strip is labeled sigma equal to 2 into 10 to the power minus 6 C by m squared.

a. Φ = 3.39 × 10 3 N · m 2 / C ; b. Φ = 0 ;
c. Φ = −2.25 × 10 5 N · m 2 / C ;
d. Φ = 90.4 N · m 2 / C

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A point charge q is located at the center of a cube whose sides are of length a . If there are no other charges in this system, what is the electric flux through one face of the cube?

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A point charge of 10 μ C is at an unspecified location inside a cube of side 2 cm. Find the net electric flux though the surfaces of the cube.

Φ = 1.13 × 10 6 N · m 2 /C

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A net flux of 1.0 × 10 4 N · m 2 /C passes inward through the surface of a sphere of radius 5 cm. (a) How much charge is inside the sphere? (b) How precisely can we determine the location of the charge from this information?

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A charge q is placed at one of the corners of a cube of side a , as shown below. Find the magnitude of the electric flux through the shaded face due to q . Assume q > 0 .

Figure shows a cube with length of each side equal to a. The back surface of it is shaded. One front corner has a small circle on it labeled q.

Make a cube with q at the center, using the cube of side a . This would take four cubes of side a to make one side of the large cube. The shaded side of the small cube would be 1/24th of the total area of the large cube; therefore, the flux through the shaded area would be
Φ = 1 24 q ε 0 .

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The electric flux through a cubical box 8.0 cm on a side is 1.2 × 10 3 N · m 2 /C . What is the total charge enclosed by the box?

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The electric flux through a spherical surface is 4.0 × 10 4 N · m 2 /C . What is the net charge enclosed by the surface?

q = 3.54 × 10 −7 C

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A cube whose sides are of length d is placed in a uniform electric field of magnitude E = 4.0 × 10 3 N/C so that the field is perpendicular to two opposite faces of the cube. What is the net flux through the cube?

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Repeat the previous problem, assuming that the electric field is directed along a body diagonal of the cube.

zero, also because flux in equals flux out

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A total charge 5.0 × 10 −6 C is distributed uniformly throughout a cubical volume whose edges are 8.0 cm long. (a) What is the charge density in the cube? (b) What is the electric flux through a cube with 12.0-cm edges that is concentric with the charge distribution? (c) Do the same calculation for cubes whose edges are 10.0 cm long and 5.0 cm long. (d) What is the electric flux through a spherical surface of radius 3.0 cm that is also concentric with the charge distribution?

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Source:  OpenStax, University physics volume 2. OpenStax CNX. Oct 06, 2016 Download for free at http://cnx.org/content/col12074/1.3
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