Magnetic Field of a Thin Conducting Plate

AI Thread Summary
A large, thin conducting plate in the x-y plane carries a uniformly distributed current in the y direction. To find the magnetic field at a distance from the plate, Ampere's Law can be applied, focusing on a closed loop that captures the magnetic field lines, which are parallel to the plate. A rectangular path is suggested for the application of Ampere's Law, emphasizing that only sections where the magnetic field is parallel to the path should be considered. The current flowing through the enclosed area can be calculated based on the current density, σ, which represents the current per meter of the plate. Properly visualizing the setup and drawing the rectangular loop is crucial for solving the problem effectively.
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A very, large, thin conducting plate lies in the x-y plane. The plate carries a current in the y direction. The current is uniformly distributed over the plate with σ amperes flowing across each meter of length perpendicular to the current. Use Ampere's Law to find the magnetic field at some distance from the plate. (Hint: The magnetic field lines are parallel to the plate.)

Homework Equations


Ampere's Law:
∫B|| ds = μ0*I

3. The Attempt at a Solution :
I'm completely lost on where to even start this question. I guess that you may have to use a Gausian cylinder or rectangular prism.
 
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dww52 said:
A very, large, thin conducting plate lies in the x-y plane. The plate carries a current in the y direction. The current is uniformly distributed over the plate with σ amperes flowing across each meter of length perpendicular to the current. Use Ampere's Law to find the magnetic field at some distance from the plate. (Hint: The magnetic field lines are parallel to the plate.)

Homework Equations


Ampere's Law:
∫B|| ds = μ0*I

3. The Attempt at a Solution :
I'm completely lost on where to even start this question. I guess that you may have to use a Gausian cylinder or rectangular prism.

For Ampere's Law, instead of a surface you are looking for a closed loop to draw somewhere. In general, the geometry of the problem might suggest some simple shape -- often a circle or rectangle -- that will make things work out.
 
So if I use a rectangular wire around the plate, do I only include the top and bottom portions of the length, since these are the only sections where the B is perpendicular to the path?

Also how do I calculate the current, is it just equal to σ?
 
dww52 said:
So if I use a rectangular wire around the plate, do I only include the top and bottom portions of the length, since these are the only sections where the B is perpendicular to the path?
Yes, use a rectangular path. But have a look again at Ampere's Law, you are looking for sections where B is parallel to the path:
dww52 said:
Ampere's Law:
∫B|| ds = μ0*I
"B||" means the component of B that is parallel to the the length element ds.

Also how do I calculate the current, is it just equal to σ?
σ is the current in 1 meter of plate. So if the rectangle encloses 1 meter of the plate, yes. If the rectangle encloses some other length, then no.

Have you drawn the rectangular loop yet? The thin plate should appear as a line in the figure, with the current directed either out of or into the page.
 

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