A charge moves with a speed `v` in a circular path of radius `r` around a long uniformly charged conductor.

A particle of mass m moves with constant speed v on a circular path of radius r as shown in figure. The average force on it during its motion from A to B is

A particle of mass m moves with constant speed v on a circular path of radius r. Find magnitude of average force on it in half revolution.

A particle moves with constant speed v along a circular path of radius r and completes the circle in time T. The acceleration of the particle is

STATEMENT-1: It is possible for a charged particle to move in a circular path around a uniformly charged long conductor. STATEMENT-2: The electrostatic force on the moving particle is directed towards the conductor.

A positive charge Q is fixed at a point in space. There is another charge -q, which moves in a circular path of radius r around the given fixed charge . Assume that the electrostatic force between them is the only force acting on them. Calculate time period of revolution of charge .

An electron of charge e is moving in a circular orbit of radius r around a nucleus, at a frequency v. The magnetic moment associated with the orbital motion of the electron is

If a charged particle having charge q is moving in a circular path of radius R with a uniform speed u, what would be the magnetic field at the centre?

When an electron moves in a circular path around a stationay nucles charge at the center

A particle of charge -q and mass m moves in a circle of radius r around an infinitely long line charge of linear charge density +lamda . Then, time period will be where , k=1/4piepsilon_0)