A neutral particle at rest in a magnetic field decays into two charged particles of different mass. The energy released goes into their kinetic energy. Then what can be the path of the particles. Neglect any interaction between the two charges.

A neutral particle is at rest in a uniform magnetic field B . At time t = 0 it decays into two charged particles, each of mass m . (a) If the charge of one of the particles is +q , what is the charge of the other? (b) The two particles move off in separate paths, both of them lie in the plane perpendicular to B . At a later time, the particles collide. Express the time from decay until collision in terms of m, B and q .

A charged particle is moved along a magnetic field line. The magnetic force on the particle is

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

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

If the ratio of time periods of circular motion of two charged particles in magnetic field in 1//2 , then the ratio of their kinetic energies must be :

A charged particle enters in a magnetic field B with its initial velocity making an angle of 45° with B. The path of the particle will be

A charged particle of mass m and charge q is released from rest in an electric field of constant magnitude E . The kinetic energy of the particle after time t is

The energy of a charged particle moving in uniform magnetic field does not change-Explain.

A charged particle enters a region of uniform magnetic field at an angle of 85^@ to the magnetic line of force. The path of the particle is a circle. Is this statement true or false?

The magnetic force on a charged particle is always perpendicular to its velocity. Can the magnetic force change the velocity of the particle? Speed of the particle?