Home
Class 8
PHYSICS
When a charged particle, moving with a v...

When a charged particle, moving with a velocity v, is subjected .to a magnetic field, the force on it is non-zero. This implies that

A

angle between them is either `0^@` or `180^@`

B

angle between them is necessarily `90^@`

C

angle between them can have any value other than `90^@`

D

angle between them can have any value other than `0^@` and `180^@`

Text Solution

AI Generated Solution

To solve the problem, we need to understand the relationship between the charged particle's velocity, the magnetic field, and the force acting on the particle. The force on a charged particle moving in a magnetic field is given by the Lorentz force equation: \[ F = q(v \times B) \] Where: - \( F \) is the magnetic force, - \( q \) is the charge of the particle, - \( v \) is the velocity of the particle, ...
Promotional Banner

Similar Questions

Explore conceptually related problems

When a charged particle moving with a velocity vecv is subjected to a magnetic field vecB , the force acting on it is non zero. Would the particle gain any energy?

When a charged particle moving with velocity vec(V) is subjected to a magnetic field of induction vec(B) the force on it is non-zero. This implies that:

Force on a charged particle moving with velocity vecv subjected to a magnetic field is zero. This means:

A charged particle moving with velocity vis subjected to electric field E and magnetic field B. The particle will go undeflected if

When a charged particle moves in an elecltric or a magnetic field, its speed is v and acceleration is a