An electron with mass m, velocity v and charge e describe half a revolution in a circle of radius r in a magnetic field B. It will acquire energy equal to

A charged particle of mass m and charge q describes circular motion of radius r in a uniform magnetic field of strength B the frequency of revolution is

An electron makes ( 3 xx 10^5) revolutions per second in a circle of radius 0.5 angstrom. Find the magnetic field B at the centre of the circle.

An electron of mass m and charge e is accelerated by a potential difference V. It then enters a uniform magnetic field B applied perpendicular to its path. The radius of the circular path of the electron is

A charged particle of mass m and charge q travels on a circular path of radius r that is perpendicular to a magnetic field B . The time takeen by the particle to complete one revolution is

In mass spectrometer used for measuring the masses of ions, the ions are initaily accerlerated by an electric potential V and then made to describe semicircular paths of radius R using a magnetic field B .if V and B are kept constant, the ratio (("charg e on the ion")/("mass of the ion")) will be propertional to:

An electron is moving on a circular path of radius r with speed v in a transverse magnetic field B. e/m for it will be

A proton of mass m and charge +e is moving in a circular orbit in a magnetic field with energy 1 MeV . What should be the energy of alpha-particle (mass= 4m and charge= +2e ), so that it can revolve in the path of same radius?

A charged particle of mass m is moving with a speed u in a circle of radius r. If the magnetic field induction at the centre is B, the charge on the particle is

If an electron is moving with velocity v in an orbit of radius r then the equivalent magnetic field at the centre will be:

A proton of mass m and charge q enters a region of uniform magnetic field of a magnitude B with a velocity v directed perpendicular to the magnetic field. It moves in a circular path and leaves the magnetic field after completing a quarter of a circle. The time spent by the proton inside the magnetic field is proportional to: