6.3 Applying gauss’s law (Page 6/13)

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Check Your Understanding A thin straight wire has a uniform linear charge density $λ_{0} .$ Find the electric field at a distance d from the wire, where d is much less than the length of the wire.

$\vec{E} = \frac{λ_{0}}{2 π ε_{0}} \frac{1}{d} \hat{r}$ ; This agrees with the calculation of [link] where we found the electric field by integrating over the charged wire. Notice how much simpler the calculation of this electric field is with Gauss’s law.

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Charge distribution with planar symmetry

A planar symmetry of charge density is obtained when charges are uniformly spread over a large flat surface. In planar symmetry, all points in a plane parallel to the plane of charge are identical with respect to the charges.

Consequences of symmetry

We take the plane of the charge distribution to be the xy -plane and we find the electric field at a space point P with coordinates ( x , y , z ). Since the charge density is the same at all ( x , y )-coordinates in the $z = 0$ plane, by symmetry, the electric field at P cannot depend on the x - or y -coordinates of point P , as shown in [link] . Therefore, the electric field at P can only depend on the distance from the plane and has a direction either toward the plane or away from the plane. That is, the electric field at P has only a nonzero z -component.

Uniform charges in xy plane: $\vec{E} = E (z) \hat{z}$

where z is the distance from the plane and $\hat{z}$ is the unit vector normal to the plane. Note that in this system, $E (z) = E (− z),$ although of course they point in opposite directions.

Figure shows a plane. Points q1 and q2 are on the plane, equidistant from its center. Lines connect these points to a point P above the plane. Arrows labeled vector E1 and vector E2 originate from point P and point in directions opposite to the lines connecting P to q1 and q2 respectively. A third arrow from P bisects the angle made by the first two arrows. This is labeled vector E subscript net. — The components of the electric field parallel to a plane of charges cancel out the two charges located symmetrically from the field point P . Therefore, the field at any point is pointed vertically from the plane of charges. For any point P and charge $q_{1},$ we can always find a $q_{2}$ with this effect.

Gaussian surface and flux calculation

In the present case, a convenient Gaussian surface is a box, since the expected electric field points in one direction only. To keep the Gaussian box symmetrical about the plane of charges, we take it to straddle the plane of the charges, such that one face containing the field point P is taken parallel to the plane of the charges. In [link] , sides I and II of the Gaussian surface (the box) that are parallel to the infinite plane have been shaded. They are the only surfaces that give rise to nonzero flux because the electric field and the area vectors of the other faces are perpendicular to each other.

Figure shows a cuboid and a plane through its center. The top and bottom surfaces of the cuboid are parallel to the plane and are labeled Slide 1 and Slide 2 respectively. An arrow labeled vector E subscript P originates from point P at the center of the top surface and points upwards, perpendicular to the surface. Another arrow labeled delta vector A also points up from the top surface. Two arrows labeled vector E and delta vector A point downward from the bottom surface. An arrow delta vector A originates from the right surface and points outward, perpendicular to the surface. Another arrow originates from its base. It is labeled vector E and points up. — A thin charged sheet and the Gaussian box for finding the electric field at the field point P . The normal to each face of the box is from inside the box to outside. On two faces of the box, the electric fields are parallel to the area vectors, and on the other four faces, the electric fields are perpendicular to the area vectors.

Let A be the area of the shaded surface on each side of the plane and $E_{P}$ be the magnitude of the electric field at point P . Since sides I and II are at the same distance from the plane, the electric field has the same magnitude at points in these planes, although the directions of the electric field at these points in the two planes are opposite to each other.

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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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