F=qvB: Questions about Charge & Velocity

  • Thread starter kelvin490
  • Start date
In summary: So in summary, a charge will experience a force and be moved if a magnet is moved close to it, regardless of the charge's own velocity. This is due to the interplay between the magnetic and electric fields created by the charge and the moving magnet.
  • #1
kelvin490
Gold Member
228
3
In applying F=qvB, must the charge move with velocity V? Or the V is only relative velocity so that even the charge is stationary but the magnetic field is moving the same result (force) can be achieve?
 
Physics news on Phys.org
  • #2
Think about the difference between a motor and a generator. How would you describe the forces involved?
 
  • #3
yes, all velocities are relative. Relative motion produces the force...
 
  • #4
kelvin490 said:
In applying F=qvB, must the charge move with velocity V? Or the V is only relative velocity so that even the charge is stationary but the magnetic field is moving the same result (force) can be achieve?

In any reference frame a charge q has a velocity v. The force due to the magnetic filed is qvxB. This is a part of the Newton equations. The magnetic filed B can be space-time dependent or constant, whatever. But if the charge velocity is equal to zero, no magnetic force is possible: this term equals zero. Only electric qE, elastic kx, etc., may still act. To keep a charge at rest, all forces should cancel in the Newton equations. Otherwise it will move under qE, for example.
 
Last edited:
  • #5
Bob_for_short said:
In any reference frame a charge q has a velocity v. The force due to the magnetic filed is qvxB. This is a part of the Newton equations. The magnetic filed B can be space-time dependent or constant, whatever. But if the charge velocity is equal to zero, no magnetic force is possible: this term equals zero. Only electric qE, elastic kx, etc., may still act. To keep a charge at rest, all forces should cancel in the Newton equations. Otherwise it will move under qE, for example.

thanks.

What if we have a reference frame that the charge is at rest, but a magnet is move close to it? Will it experience a force and be moved?
 
  • #6
kelvin490 said:
...What if we have a reference frame that the charge is at rest, but a magnet is move close to it? Will it experience a force and be moved?

Yes, it will. A moving magnet, apart from magnetic field creates an electrical field E determined with the magnet velocity, so the total force will be non-zero.

The value of electrical filed E can be calculated from the Lorentz transformations for fields. In the non relativistic approximation it will be EVxB where V is the magnet velocity.
 
Last edited:

FAQ: F=qvB: Questions about Charge & Velocity

1. What is the equation F=qvB used for?

The equation F=qvB is used to calculate the force (F) experienced by a charged particle moving with a velocity (v) in a magnetic field (B).

2. How do charge and velocity affect the force on a particle in a magnetic field?

The force on a charged particle in a magnetic field is directly proportional to both the charge (q) and velocity (v) of the particle. This means that increasing either the charge or velocity will result in a greater force.

3. What is the direction of the force on a charged particle in a magnetic field?

The direction of the force on a charged particle in a magnetic field is perpendicular to both the direction of the particle's velocity and the direction of the magnetic field. This is known as the right-hand rule, where the thumb points in the direction of the particle's velocity, the index finger points in the direction of the magnetic field, and the middle finger points in the direction of the force.

4. Can this equation be used for any type of charged particle?

Yes, the equation F=qvB can be used for any type of charged particle, as long as the charge and velocity are known. This includes electrons, protons, and other particles with a charge.

5. How is this equation related to the Lorentz force?

The equation F=qvB is a part of the Lorentz force equation, which also includes the electric field (E). The Lorentz force equation is used to calculate the total force on a charged particle in both electric and magnetic fields. The F=qvB equation specifically calculates the force due to the magnetic field.

Similar threads

B Why does a magnet attract metal objects?
Replies
2
Views
688
What is the induced magnetic force on this closed current loop?
Replies
12
Views
844
I Question about magnetohydrodynamics (MHD) for electricity production
Replies
4
Views
749
Total Force on a Point Charge in Motion
Replies
18
Views
1K
B Greater momentum on impact means greater force?
3
Replies
75
Views
4K
B Does the Electric Field Change When One Charge Moves Relative to Another?
Replies
7
Views
906
B A question about induced current in LC circuits
Replies
4
Views
677
I When does the instantaneous velocity exist?
Replies
4
Views
1K
B Can charges move without a field? How charges redistribute without it?
Replies
16
Views
815
B A Magnetic Misconception on Divergence 0/Closed Field Lines?
Replies
3
Views
640

Hot Threads

Recent Insights

Back
Top