Understanding the Lorentz Force

In summary, the Lorentz force on electrons and positive charges both points up when considering a magnetic field perpendicular to the direction of current. This may seem contradictory, but it is because they are moving in different directions. However, the magnetic force exerted on the wire depends only on the current, not on the sign of the charge carriers. The sign of the charge carriers does determine the sign of the Hall voltage, but this does not change the fact that the magnetic force depends solely on the current. This realization may have played a role in the discovery of electrons as the charge carriers in motion.
  • #1
ehrenfest
2,020
1
[SOLVED] lorentz force

Homework Statement


Say you a magnetic field perpendicular to the direction of a current. If you consider the current as electrons moving forward then the Lorentz force on the electrons points up (say). But if you consider the current is a lot of positive charge carriers moving backward, then the Lorentz force on the positive charges points up also because the sign of the cross-product and the sign of the charge changes. That makes ABSOLUTELY NO SENSE TO ME because how can the positive charge carriers and the electrons both move up?


Homework Equations





The Attempt at a Solution

 
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  • #2
because they are moving in different directions.
 
  • #3
olgranpappy said:
because they are moving in different directions.

but the current is moving in the same direction in both cases
 
  • #4
ehrenfest said:
but the current is moving in the same direction in both cases

Then that's a good thing. It's telling you the magnetic force exerted on the wire just depends on the current, not on the sign of the charge carriers. I don't see why that would bother you. Don't we already know that?
 
  • #5
Dick said:
Then that's a good thing. It's telling you the magnetic force exerted on the wire just depends on the current, not on the sign of the charge carriers. I don't see why that would bother you. Don't we already know that?

What bothers me is that for a given current, the sign of the charge carriers determine the sign of the hall voltage

http://en.wikipedia.org/wiki/Image:Hall-effect.png
 
  • #6
Sure. As you've observed if the charge carriers are negative, they accumulate on the 'up' side of the conductor. If they are positive they also accumulate on the 'up' side. That's two different signs of potential across the conductor.
 
  • #7
Dick said:
Sure. As you've observed if the charge carriers are negative, they accumulate on the 'up' side of the conductor. If they are positive they also accumulate on the 'up' side. That's two different signs of potential across the conductor.


So, I guess it was just naive to think that the sign of the transverse electric field would depend only on the current not on what is actually carrying the charge. Maybe that is how they discovered that electrons were the ones in motion...
 
  • #8
indeed.
 

What is the Lorentz Force?

The Lorentz Force is a fundamental concept in electromagnetism that describes the force exerted on a charged particle by an electric and magnetic field. It was first described by Dutch physicist Hendrik Lorentz in the late 19th century.

What are the components of the Lorentz Force?

The Lorentz Force has two components: the electric force, which is proportional to the electric field and the charge of the particle, and the magnetic force, which is proportional to the magnetic field, the charge of the particle, and its velocity.

How is the Lorentz Force calculated?

The Lorentz Force can be calculated using the equation F = q(E + v x B), where F is the force, q is the charge of the particle, E is the electric field, v is the velocity of the particle, and B is the magnetic field. This equation takes into account both the electric and magnetic components of the force.

What is the importance of the Lorentz Force?

The Lorentz Force is essential for understanding the behavior of charged particles in electric and magnetic fields. It is used in many applications such as particle accelerators, electric motors, and generators. It also plays a crucial role in the study of electromagnetism and is a fundamental concept in the field of physics.

Can the Lorentz Force be manipulated or controlled?

Yes, the Lorentz Force can be manipulated and controlled by changing the strength and direction of the electric and magnetic fields. This is often used in practical applications to move and manipulate charged particles for various purposes, such as in medical imaging and particle physics experiments.

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