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--- 184_notes:examples:week5_flux_cylinder_line [2017/09/19 13:52] – tallpaul
+++ 184_notes:examples:week5_flux_cylinder_line [2021/06/04 00:54] (current) – schram45
@@ Line 1: / Line 1: @@
+[[184_notes:q_enc|Return to Enclosed Charge notes]]
 =====Example: Flux through a Cylinder on a Line of Charge=====
-Suppose you have a line of charge with a uniform linear charge density of  $\lambda=15\mu\text{C/m}$ . What is the electric flux through a cylinder with radius  $R=0.5 \text{ m}$ , and length  $l=3 \text{ m}$  that is placed so that its axis is aligned with the line of charge? Feel free to use the electric field due to an infinite uniform plane of charge: $\vec{E} = \frac{\sigma}{2\epsilon_0}(\pm\hat{z}) $(where$ \pm\hat{z}$ points away from plane). Notice that the strength of the electric field does not depend on the distance from the plane -- it is constant apart from a change in direction when you cross over to the other side of the plane.
+Suppose you have a line of charge with a uniform linear charge density of  $\lambda=15\mu\text{C/m}$ . What is the electric flux through a cylinder with radius  $R=0.5 \text{ m}$ , and length  $l=3 \text{ m}$  that is placed so that its axis is aligned with the line of charge? Feel free to use the electric field due to an infinite uniform line of charge: $\vec{E} = \frac{\lambda}{2\pi r\epsilon_0}\hat{r} $(where$ \hat{r}$ points away from line, and  $r$  is the distance from the line).
 ===Facts===
-  * The cube has side-length $l=0.5 \text{ m}$.
+  * The cylinder has radius $R=0.5 \text{ m} $, and length$ l=3 \text{ m}$.
-  * The cube is halfway into the plane -- presumably this means the plane bisects the cube.
+  * The axis of the cylinder is aligned with the line charge.
-  * The plane has surface charge density $\sigma=-4\mu\text{C/m}^2$.
+  * The line charge has linear charge density $\lambda=15\mu\text{C/m}$.
 ===Lacking===
-  *  $\Phi_e$  for the cube.
+  *  $\Phi_e$  for the cylinder.
-===Approximations & Assumptions===
-  * There are no other charges that contribute appreciably to the flux calculation.
-  * The cube is aligned with respect to the plane so that all of its faces are either parallel or perpendicular to the plane.
 ===Representations===
   * We represent the electric flux through a surface with:
  $\Phi_e=\int\vec{E}\bullet \text{d}\vec{A}$
-  * We represent the electric field due to a plane of uniform surface charge density with:
+  * We represent the electric field due to an infinite line of uniform charge density with:
-$$\vec{E} = \frac{\sigma}{2\epsilon_0}(\pm\hat{z})$$
+$$\vec{E} = \frac{\lambda}{2\pi r\epsilon_0}\hat{r}$$
   * We represent the situation with the following diagram.
-{{ 184_notes:5_cube_plane.png?400 |Charged Plane and Cubic Surface}}
+[{{ 184_notes:5_cylinder_line.png?400 |Charged Line and Cylindrical Surface}}]
+<WRAP TIP>
+===Approximations & Assumptions===
+There are a few approximations and assumptions we should make in order to simplify our model.
+  * There are no other charges that contribute appreciably to the flux calculation.
+  * The cylinder is aligned with respect to the line so that its bases are perpendicular to the line, and its wall is parallel (as described). This is just a geometric simplification for the model, and ensures the electric field through the cylinder wall is constant as the wall will be at a uniform distance away from the line of charge at any point.
+  * Line of charge is very very long: This allows us to use the electric field equation provided in the problem statement, and ensures the electric field is constant through the wall of our cylinder.
+</WRAP>
 ====Solution====
-First, we evaluate the situation qualitatively. Consider the electric field lines of the charged plane:
+First, we evaluate the situation qualitatively. Consider the electric field vectors from the charged line near the surface of the cylinder:
-{{ 184_notes:5_plane_field_lines.png?400 |Negatively Charged Plane -- Electric Field Lines}}
+[{{ 184_notes:5_line_field_lines.png?400 ||Positively Charged Line -- Electric Field Lines}}]
-You might notice that we have oriented the cube conveniently. The electric field is parallel to the sides of the cube, so there are no electric field lines entering or exiting from the side of the cube. So the flux through the sides should be  $0$ . For the top and bottom of the cube, the electric field lines are perpendicular to the surface, which means they are parallel to the area-vectors. These facts will greatly simplify our integral calculation of the flux.
+It's a little tough to demonstrate the electric field vectors with only two dimensions to draw on, but you can imagine that the thicker arrows point out of the page more, and the thinner arrows point into the page more (but the magnitude of the arrows are all the same). In essence, each vector points directly away from and perpendicular to the line of charge, as indicated in the formula for electric field from a line charge.
+The electric field vectors are parallel to the bases of the cylinder, so  $\vec{E}\bullet\text{d}\vec{A}=0$  on the bases. So the flux through the bases should be  $0$ . For the wall of the cylinder, the electric field vectors are perpendicular to the surface, which means they are parallel to the area-vectors. These facts will greatly simplify our integral calculation of the flux.
 \begin{align*}
-\Phi_{\text{total}} &= \Phi_{\text{sides}}+\Phi_{\text{top}}+\Phi_{\text{bottom}} \\
+\Phi_{\text{total}} &= \Phi_{\text{bases}}+\Phi_{\text{wall}} \\
-                    &= 0 + \int_{\text{top}}\vec{E}\bullet \text{d}\vec{A} + \int_{\text{bottom}}\vec{E}\bullet \text{d}\vec{A} \\
+                    &= 0 + \int_{\text{wall}}\vec{E}\bullet \text{d}\vec{A} \\
-                    &= \int_{\text{top}}E\hat{z}\bullet \text{d}A\hat{z} + \int_{\text{bottom}}E(-\hat{z})\bullet \text{d}A(-\hat{z}) \\
+                    &= \int_{\text{wall}}E\hat{r}\bullet \text{d}A\hat{r} \\
-                    &= E\int_{\text{top}}\text{d}A + E\int_{\text{bottom}}\text{d}A \\
+                    &= E\int_{\text{wall}}\text{d}A \\
-                    &= E\cdot(A_{\text{top}}+A_{\text{bottom}}) \\
+                    &= EA_{\text{wall}} \\
-                    &= \frac{\sigma}{2\epsilon_0}(2l^2) \\
+                    &= \frac{\lambda}{2\pi R \epsilon_0}\cdot 2\pi R l \\
-                    &= \frac{\sigma l^2}{\epsilon_0}
+                    &= \frac{\lambda l}{\epsilon_0}
 \end{align*}
-When we plug in values for $\sigma $,$ l $, and$ \epsilon_0 $, we get$ \Phi_{\text{cube}}=1.15\cdot 10^5\text{ Vm}$.
+When we plug in values for $\lambda $,$ l $, and$ \epsilon_0 $, we get$ \Phi_{\text{cylinder}}=5.08\cdot 10^6\text{ Vm}$.
-Notice that in the [[184_notes:gauss_ex|next section of notes]], we define "Gauss' Law", which states that the total flux through a close surface is the amount of charge enclosed divided by  $\epsilon_0$ . A quick check for this example shows us that the charge enclosed by the sphere covers an area of $l^2 $, which means the charge is$ \sigma\cdot l^2$. If we had used Gauss' Law, we would have quickly found that
+Notice that in the [[184_notes:gauss_ex|next section of notes]], we define "Gauss' Law", which states that the total flux through a close surface is the amount of charge enclosed divided by  $\epsilon_0$ . A quick check for this example shows us that the charge enclosed by the cylinder covers a length of  $l$ , which means the charge is $\lambda l$. If we had used Gauss' Law, we would have quickly found that
-$$\Phi_{\text{cube}}=\frac{Q_{\text{enclosed}}}{\epsilon_0}=\frac{\sigma l^2}{\epsilon_0}$$
+$$\Phi_{\text{cylinder}}=\frac{Q_{\text{enclosed}}}{\epsilon_0}=\frac{\lambda l}{\epsilon_0}$$
-This is the same result! An alternative question for this example could have been: What is the electric field due to a uniformly charged plane? If we were not given the electric field at the beginning, we could have used symmetry arguments and Gauss' Law to work backwards, starting with the charge enclosed, and then using the integral formula for electric flux to solve for the electric field. There are sometimes electric fields that we do not know off-hand, and Gauss' Law is often the best tool to find them.
+This is the same result! An alternative question for this example could have been: What is the electric field due to a uniformly charged line? If we were not given the electric field at the beginning, we could have used symmetry arguments and Gauss' Law to work backwards, starting with the charge enclosed, and then using the integral formula for electric flux to solve for the electric field. There are sometimes electric fields that we do not know off-hand, and Gauss' Law is often the best tool to find them.