Loop, compass and magnetic field

AI Thread Summary
A compass placed in a metal loop with a radius of 0.10m deviates by 2 degrees when the loop rotates at a constant angular velocity. The discussion focuses on calculating the resistance R of the loop based on the induced magnetic field. Participants suggest using the Biot-Savart law to determine the magnetic field strength at the center of the loop. There is a query about alternative methods to solve the problem without relying on the Biot-Savart law. The conversation emphasizes understanding the relationship between the loop's motion and the compass's deviation.
Mantaray
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Homework Statement


A compass is placed in the middle of a metal loop with radius 0.10m. The compass points in the direction of the Earth magnetic field when the loop is at rest. When the loop revolves around an axis perpendicular to the Earth's surface with constant angular velocity, the average deviation of the compass needle is 2 degrees. Find the resistance R of the metal loop.

Homework Equations



Relevant Equations and attempt at solution are both in the .pdf file.

The Attempt at a Solution

 

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Mantaray said:

Homework Statement


A compass is placed in the middle of a metal loop with radius 0.10m. The compass points in the direction of the Earth magnetic field when the loop is at rest. When the loop revolves around an axis perpendicular to the Earth's surface with constant angular velocity, the average deviation of the compass needle is 2 degrees. Find the resistance R of the metal loop.

Homework Equations



Relevant Equations and attempt at solution are both in the .pdf file.

The Attempt at a Solution


You are on the right track. Here's a link to help you calculate the B-field at the center of the loop of current:

http://hyperphysics.phy-astr.gsu.edu/hbase/magnetic/curloo.html

.
 
Thank you!
Knowing that the magnetic field strength induced by the loop equals, I could decompose that vector into one which is parallel to the Earth magnetic field by multiplying with sin(omega t) and one which is perpendicular to the Earth magnetic field by multiplying with cos(omega t).
I think I'm able to work out the answer from here on.

However, is there an additional way to solve this problem without applying the Biot-Savart law, or is it mandatory to first deduce the Biot-Savart law from Ampère's law?
 
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