Charge passing through a magnetic field of uniform magnetic flux density

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The discussion centers on the behavior of a charged particle moving through a uniform magnetic field, where the magnetic force acts as a centripetal force, causing the charge to follow a circular path. The total force on the charge is described by the Lorentz force equation, combining both electric and magnetic forces. To counteract the circular motion and achieve straight-line movement, an electric field must be applied, which is a combination of x and y coordinates. The net force on the charge is zero when it moves at constant speed in a straight line, indicating no acceleration. The necessary electric field to maintain this straight-line motion is derived from the initial velocity and magnetic flux density.
3OPAH
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My reasoning:

The magnetic force on charge q is

Fm = qv x B

B does not change |v|. Therefore, |Fm| is constant at time t > 0 and Fm is always perpendicular to the direction of movement of charge q. Fm behaves as a centripetal force, and thus the charge moves along the circumference of a circle.

Here is my drawing depicting what I think is happening:
upload_2015-4-5_11-47-25.png


Now, knowing that an electric charge q either at rest or in motion, experience an electric force Fe in the presence of an electric field E, that is,


Fe = qE

Then if we have a charge q moving with velocity v in the presence of both an electric field E and a magnetic flux density B, the total force exerted on the charge is therefore

F = Fe + Fm = q(E + v x B)

which is the Lorentz force equation.

I am having trouble using what I have done so far and what I know about the magnetic force and electric force to compute the necessary electric force needed to make charge q move in a straight line. If the charge is moving in a circular path about the xy-plane under the influence of a magnetic field in the positive z direction, then the necessary electric field needed to counteract the circular movement of the charge and make it move in a straight line will be a combination of x and y coordinates, correct?
 
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3OPAH said:
then the necessary electric field needed to counteract the circular movement of the charge and make it move in a straight line will be a combination of x and y coordinates, correct?
Correct.

What is the net force on the charge if it moves in a straight line at constant speed*?

*this is not required, but if you allow a variable speed things get really messy
 
mfb said:
Correct.

What is the net force on the charge if it moves in a straight line at constant speed*?

*this is not required, but if you allow a variable speed things get really messy

If a charge experiences no net force, then its velocity is constant; the charge is either at rest (if its velocity is zero), or it moves in a straight line with constant speed. So the net force is zero.
 
mfb said:
Right.

So we are given the initial velocity of v = aex + bey. The magnitude of the velocity vector has to be the same, but opposite in direction. So the necessary electric field is (with the magnetic flux density in there as well):

E = -bB_0ex + aB_0ey

correct?
 

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