184_notes:examples:week5_flux_tilted_surface

Differences

This shows you the differences between two versions of the page.

Link to this comparison view

Both sides previous revision Previous revision
Next revision		 Previous revision
184_notes:examples:week5_flux_tilted_surface [2017/09/24 18:50] – [Solution] tallpaul184_notes:examples:week5_flux_tilted_surface [2021/06/04 00:41] (current) schram45
Line 1: Line 1:
 +[[184_notes:e_flux|Return to Electric Flux and Area Vectors notes]]
 +
 =====Example: Flux through a Tilted Surface===== =====Example: Flux through a Tilted Surface=====
 Suppose you have a uniform electric field $\vec{E} = 8\text{ V/m } \hat{x}$. There is a tilted rectangular surface with dimensions $3\text{ m}$ (perpendicular to the field), and $5\text{ m}$ (at an angle of $\theta=30^\circ$ to field). What is the electric flux through the surface? Suppose you have a uniform electric field $\vec{E} = 8\text{ V/m } \hat{x}$. There is a tilted rectangular surface with dimensions $3\text{ m}$ (perpendicular to the field), and $5\text{ m}$ (at an angle of $\theta=30^\circ$ to field). What is the electric flux through the surface?
Line 10: Line 12:
   * $\Phi_e$   * $\Phi_e$
   * $\vec{A}$   * $\vec{A}$
- 
-===Approximations & Assumptions=== 
-  * The electric field is constant. 
-  * The surface is flat. 
-  * The electric flux through the surface is due only to $\vec{E}$. 
  
 ===Representations=== ===Representations===
Line 20: Line 17:
 $$\Phi=\vec{E}\bullet \vec{A}$$ $$\Phi=\vec{E}\bullet \vec{A}$$
   * We represent the situation with the following diagram. Note that the top of the rectangle aligns along the $z$-direction, but we represent using a perspective that also shows area. The little coordinate axes drawn may be unfamiliar. The circle with the dot simply means that the $+z$-axis comes straight out of the page. A circle with an X would mean into the page. Just think of an arrow either seen head-on (all you see is the point), or seen from behind (you see the feathers).   * We represent the situation with the following diagram. Note that the top of the rectangle aligns along the $z$-direction, but we represent using a perspective that also shows area. The little coordinate axes drawn may be unfamiliar. The circle with the dot simply means that the $+z$-axis comes straight out of the page. A circle with an X would mean into the page. Just think of an arrow either seen head-on (all you see is the point), or seen from behind (you see the feathers).
-{{ 184_notes:5_flux_flat_angle.png?400 |Tilted Surface}}+[{{ 184_notes:5_flux_flat_angle.png?400 |Tilted Surface}}
 + 
 +<WRAP TIP> 
 +===Approximations & Assumptions=== 
 +There are a few simplifying approximations and assumptions we should make before solving this problem. 
 +  * The electric field is constant: Allows the electric field to be constant through our area which simplifies down the flux equation. 
 +  * The surface is flat: Allows all the area vectors associated with the surface to point in the same direction. 
 +  * The electric flux through the surface is due only to $\vec{E}$. 
 +</WRAP>
 ====Solution==== ====Solution====
 In order to find electric flux, we must first find $\vec{A}$. Remember in the [[184_notes:e_flux#Area_as_a_Vector|notes on flux]] that area can be a vector when we define it as a [[184_notes:math_review#Vector_Multiplication|cross product]] of width and length vectors. Here, we can use the following for width and length, with width being the top of the rectangle, and pointing out of the page, and length being the longer side, and pointing at an upwards angle: In order to find electric flux, we must first find $\vec{A}$. Remember in the [[184_notes:e_flux#Area_as_a_Vector|notes on flux]] that area can be a vector when we define it as a [[184_notes:math_review#Vector_Multiplication|cross product]] of width and length vectors. Here, we can use the following for width and length, with width being the top of the rectangle, and pointing out of the page, and length being the longer side, and pointing at an upwards angle:
Line 26: Line 31:
 $$\vec{l}=5\text{ m }\cdot\cos 30^\circ (\hat{x})+5\text{ m }\sin 30^\circ\hat{y} = 4.33\text{ m } \hat{x} + 2.5\text{ m }\hat{y}$$ $$\vec{l}=5\text{ m }\cdot\cos 30^\circ (\hat{x})+5\text{ m }\sin 30^\circ\hat{y} = 4.33\text{ m } \hat{x} + 2.5\text{ m }\hat{y}$$
 Now, we can find the area vector would be (using that [[183_notes:cross_product|matrix form of the cross product]]): Now, we can find the area vector would be (using that [[183_notes:cross_product|matrix form of the cross product]]):
-FIXME (I would put all the numbers in decimal form rather than trying to keep them exact with square roots...) 
 \begin{align*} \begin{align*}
 \vec{A} &= \vec{l}\times\vec{w} \\ \vec{A} &= \vec{l}\times\vec{w} \\
Line 39: Line 43:
         &= 60\text{ Vm}         &= 60\text{ Vm}
 \end{align*} \end{align*}
 +This makes sense cause the max flux through the surface would occur when the the surface was perpendicular to the electric field and the area vector was in the same direction as the electric field. This would result in a flux of $120Vm$. Since the surface in this case is $30^\circ$ away from the electric field we would expect there to be a much smaller flux due to the large angle between the area vector and the electric field.
  • 184_notes/examples/week5_flux_tilted_surface.1506279003.txt.gz
  • Last modified: 2017/09/24 18:50
  • by tallpaul