A charged particle enters into a uniform magnetic field with velocity `v_(0)` perpendicular to it, the length of magnetic field is `x=(sqrt(3)//2)` R, where R is the radius of the circular path of the particle in the field. The magnitude fo change in velocity of the particle when it comes out of the field is

A charged particle enters into a uniform magnetic field with velocity v_(0) perpendicular to it , the length of magnetic field is x=sqrt(3)/(2)R , where R is the radius of the circular path of the particle in the field .The magnitude of charge in velocity of the particle when it comes out of the field is

A charged particle enters a uniform magnetic field with velocity v_(0) = 4 m//s perpendicular to it, the length of magnetic field is x = ((sqrt(3))/(2)) R , where R is the radius of the circular path of the particle in the field. Find the magnitude of charge in velocity (in m/s) of the particle when it comes out of the field.

When a charged particle enters a uniform magnetic field its kinetic energy

A charged particle enters in a uniform magnetic field perpendicular to it. Now match the following two columns.

If a charged particle enters perpendicular in the uniform magnetic field then

A charged particle enters a uniform magnetic field perpendicular to it. The magnetic field

The path of a charged particle in a uniform magnetic field, when the velocity and the magnetic field are perpendicular to each other is a

A charged particle enters a unifrom magnetic field with velocity vector at an angle of 45^(@) with the magnetic field . The pitch of the helical path followed by the particles is rho . The radius of the helix will be

If a charged particle is a plane perpendicular to a uniform magnetic field with a time period T Then

A charged particle moves in a uniform magnetic field. The velocity of the particle at some instant makes an acute angle with the magnetic field. The path of the particle will be