Work done by the Magnetic Force The magnetic part of the Lorentz force acts perpendicular to the c

Edith Mayer

Edith Mayer

Answered question

2022-05-08

Work done by the Magnetic Force
The magnetic part of the Lorentz force acts perpendicular to the charge's velocity, and consequently does zero work on it. Can we extrapolate this statement to say that such a nature of the force essentially makes its corresponding work independent of the choice of path, and hence that the magnetic force is conservative?

Answer & Explanation

Gallichi5mtwt

Gallichi5mtwt

Beginner2022-05-09Added 18 answers

Not really, because the magnetic force is velocity dependent, not solely position dependent, so you can't extrapolate from knowing the integral along a path is zero to the conclusion that the force is the gradient of a potential.
What you can do is make an analog of the potential argument for the momentum components, so that the magnetic field is the curl of a vector potential. This argument can be made physically for conservation of momentum around a space-time loop, much like the conservation of energy follows from the integral of the force along a space-loop.
dresu9dnjn

dresu9dnjn

Beginner2022-05-10Added 7 answers

Work done by the magnetic force is indeed zero.
F m = q [ V × B ]
d W = q [ V × B ] . d r = q [ V × B ] V d t = 0
Consequently for work done along some arbitrary path from A to B
= A B d W = 0
Work done by the magnetic force is independent of path[and equal to zero for all such paths]
However we may have the following interesting consideration:
Let V = V 1 + V 2
[We may choose V 1 and V 2 so that V 1 , V 2 and B are not in the same plane]
d W = 0 = q [ ( V 1 + V 2 ) × B ] ( V 1 + V 2 ) d t
= q [ V 1 × B ] V 1 + q [ V 1 × B ] V 2 + q [ V 2 × B ] V 1 + q [ V 2 × B ] V 2
0 = q [ V 1 × B ] V 2 + q [ V 2 × B ] V 1
The quantities q [ V 1 × B ] V 2 and q [ V 2 × B ] V 1 may not be zero individually[considering tha fact that V 1 , V 2 and B do not lie in the same plane according to our choice] though their sum is zero.We might think of using either of them for some technological purpose.

Do you have a similar question?

Recalculate according to your conditions!

New Questions in Electromagnetism

Ask your question.
Get an expert answer.

Let our experts help you. Answer in as fast as 15 minutes.

Didn't find what you were looking for?

Product

Company

Connect with us

Get Plainmath App

Plainmath Logo

E-mail us: [email protected]

Our Service is useful for:

Plainmath is a platform aimed to help users to understand how to solve math problems by providing accumulated knowledge on different topics and accessible examples.

2023 Plainmath. All rights reserved