I've been stuck on this problem forever.

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Homework Help Overview

The problem involves a uniformly charged slab of insulating material with a specified thickness and charge density, and the goal is to determine the electric field at points outside the slab using Gauss's law. The context is rooted in electrostatics and the application of Gaussian surfaces.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss the use of Gaussian surfaces to calculate electric flux and relate it to the enclosed charge. Some suggest specific steps for applying Gauss's law, while others express confusion about the correctness of the derived expressions for the electric field.

Discussion Status

There is ongoing exploration of the problem, with some participants providing detailed steps and others questioning the accuracy of the results. A few participants have noted discrepancies in the expected answers, leading to further clarification attempts regarding the charge thickness and its implications on the calculations.

Contextual Notes

Participants mention the use of different online platforms for submitting answers, which may influence their understanding of the problem's requirements. There is also a noted confusion regarding the thickness of the charge, which is critical to the calculations.

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A Uniformly Charged Slab. A slab of insulating material has thickness 2d and is oriented so that its faces are parallel to the yz-plane and given by the planes x=d and x= - d. The y- and z-dimensions of the slab are very large compared to d and may be treated as essentially infinite. The slab has a uniform positive charge density rho.

Using Gauss's law, find the magnitude of the electric field due to the slab at the points x>=d.
 
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It's not tough once you've thought about it for a few years. Here is the answer.

Take a can (like one used for canned peaches) and send it through the plane of charge so that the bottom and top of the can are parallel to the plane of charge.

Now the electric flux through the can is (by gauss's law) the Integral[Dot[E,da]] where E is the electric field and da is the differential surface area is equal to 2*Pi*r^2 *E which is also equal to Q/e that is the enclosed charge divided by epsilon. But remember Q=2*pi*r^2 * d *rho.

The rest of the algebra is trivial

E=rho*d/(2e) facing in the x direction

PS. Use a symmetry argument to convince yourself that E is uniform along the top and bottom of the can and E is perpindicular to the top and bottom of the can
 
Last edited:
1st step is to draw a gaussian surface
2nd step is to find the flux = EA = E 2(pi)(r^2)
3rd step is to find the charge from the equation, rho = Q/V ; Q = rho * Volume =
(rho)[(2)(pi)(r^2)(d)]
4th step is to use gauss law, EA = Q/8.85X10^-12 and solve for E.

Epsilon = 8.85X10^-12
 
sinyud said:
It's not tough once you've thought about it for a few years. Here is the answer.

Take a can (like one used for canned peaches) and send it through the plane of charge so that the bottom and top of the can are parallel to the plane of charge.

Now the electric flux through the can is (by gauss's law) the Integral[Dot[E,da]] where E is the electric field and da is the differential surface area is equal to 2*Pi*r^2 *E which is also equal to Q/e that is the enclosed charge divided by epsilon. But remember Q=2*pi*r^2 * d *rho.

The rest of the algebra is trivial

E=rho*d/(2e) facing in the x direction

PS. Use a symmetry argument to convince yourself that E is uniform along the top and bottom of the can and E is perpindicular to the top and bottom of the can


I tried that answer and the website that I'm using to enter in answers says that the answers you gave is off by a multiplicative factor.
 
answer

exactly, my answer is the correct one.
 
My bad,

The thickness of your charge is 2*d not just d . This should work.

E=rho*d/e facing in the x direction

BTW; what website are you using? Webassign?
 
sinyud said:
My bad,

The thickness of your charge is 2*d not just d . This should work.

E=rho*d/e facing in the x direction

BTW; what website are you using? Webassign?

No, it's masteringphysics.com, made for the book I am using.
 

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