Magnetic moment and magnetic torque of a current loop

In summary, the conversation discusses the magnetic momentum and torque of a circular current loop. The magnetic moment is not defined only in the center of the loop, but rather represents the entire object. This is similar to how gravity acts on the entire donut, not just its center. The torque is dependent on the number of field lines passing through the loop, not just the center.
  • #1
Gavo
2
0
Hi.
I have a question concerning the magnetic momentum of a current loop.
We know that if we have a circular current loop (a solenoid with N=1), there is a magnetic moment (mu) in the center of the loop given by "mu=S I" (I=current, S =surface enclosed by the loop). So, if there is an external magnetic field B, we can have a torque (tau) given by "tau=mu x B".
In order to calculate this, we need to have a magnetic field with its field lines passing through the center of the surface enclosed by the loop.
What happens when we have a magnetic field with lines passing thruogh the surface of current loop, but not in the center? Would it be any torque? I guess these questions are linked to the fact that the magnetic momentum "mu" of a current loop is defined only in the center of the surface enclosed by the loop (or not?).

Thanks to everyone.
 
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  • #2
The magnetic moment is not "defined only in the center of the loop". The magnetic moment is not a field, it is a single entity attached to a single object. We draw it in the center because that is the center of action, but it describes the entire object. Think of the force on gravity on a donut. The force that the donut feels is a single entity describing the entire object. Because it is a single entity, we only draw one vector arrow. You've got to draw the arrow, somewhere, so you draw it attached to the center of mass because that is the center of action. But for a donut, there is no matter at its center, so is there a problem if we draw the force vector acting on a spot with no matter? No, this is not a problem because the force is not a field. It acts on objects, not on single points in space. So the vector drawn attached to the hole in the middle of the donut is understood to represent the total effect of gravity exerting a force on the entire donut, as if its entire mass where contained at a point which is its center of mass.
It is the same with magnetic moment, electric dipole moment, angular momentum, velocity, etc. They are single-entity vectors which only make sense when attached and describing an object (or system of objects).

For the torque law you describe, it's the number of field lines passing through anywhere in the loop that have an effect. That is why mu is dependent on the S, the entire surface area enclosed by the loop.
 
  • #3
Ok, thanks a lot, now it's clear.
 

1. What is a magnetic moment of a current loop?

The magnetic moment of a current loop is a measure of the strength and direction of the magnetic field produced by the loop. It is a vector quantity that depends on the magnitude of the current, the size and shape of the loop, and the orientation of the loop with respect to an external magnetic field.

2. How is the magnetic moment of a current loop calculated?

The magnetic moment of a current loop can be calculated using the formula μ = I * A * n, where μ is the magnetic moment, I is the current, A is the area of the loop, and n is the number of turns in the loop. This formula assumes that the loop is a perfect circle and that the current is evenly distributed around the loop.

3. What is the direction of the magnetic moment of a current loop?

The direction of the magnetic moment of a current loop is perpendicular to the plane of the loop and follows the right-hand rule. This means that if you curl the fingers of your right hand in the direction of the current, your thumb will point in the direction of the magnetic moment.

4. How does the magnetic moment of a current loop interact with an external magnetic field?

When a current loop is placed in an external magnetic field, the magnetic moment of the loop will align itself with the direction of the field. If the external field is uniform, the loop will experience a torque, or turning force, causing it to rotate until it is aligned with the field.

5. What is the relationship between magnetic moment and magnetic torque?

The magnetic torque on a current loop is directly proportional to the magnetic moment of the loop and the strength of the external magnetic field. This means that a larger magnetic moment or a stronger external field will result in a greater torque on the loop, causing it to rotate more.

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