An electron is at P `t = 0` It is circulating in anticlockwise direction with a constant angular speed `omega` along the shown circular path. Magnetic field at `Q(CQ = 2R`, where R is radius of the circular) will be recorded as zero at times)

Magnetic force acting on the charged particle projected perpendicular to magnetic field is proportional to r^(n) , where r is radius of circular path. Find n

A particle moves along a circle of radius R with a constant angular speed omega . Its displacement (only magnitude) in time t will be

A particle moves along a circle of radius R with a constant angular speed omega . Its displacement (only magnitude) in time t will be

A particle is revolving in a circular path of radius 2 m with constant angular speed 4 rad/s. The angular acceleration of particle is

An electron in the ground state of hydrogen atom is revolving in anticlockwise direction in circular orbit of radius R. The orbital magnetic dipole moment of the electron will be

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

If linear speed of a particle moving in a circular path is constant then,angular speed is proportional to (r is radius of circle)

Particles a and b move in opposite direction around a circle with same angular speed omega , as shown. At t=0 they are both at the point vecr=vect vecj , where l is the radius of the circle. The magnitude angular velocity of 'a' w.r.t. 'b' at time t=t

A thin circular ring of mass per unit length p and radius r is rotating at an angular speed omega as shown in figure. The tension in the ring is