In a hypothetical system , a particle of mass `m` and charge `-3 q` is moving around a very heavy particle charge `q`. Assume that Bohr's model is applicable to this system , then velocity of mass `m` in the first orbit is

A particle of mass m carrying charge '+q_(1)' is revolving around a fixed charge '-q_(2)' in a circular path of radius r. Calculate the period of revolution.

An imaginary particle has a charge equal to that of an electron and mass 100 times the mass of the electron. It moves in a circular orbit around a nucleus of charge + 4 e . Take the mass of the nucleus to be infinite. Assuming that the Bhor model is applicable to this system. using an expression for the radius of n^(th) Bhor orbit. Find the wavelength of the radiation emitted when the particle jumps from fourth orbit to the second orbit.

A particle of mass m and charge q is thrown in a region where uniform gravitational field and electric field are present. The path of particle:

Two charges, each equal to q, aer kept at x=-a and x=a on the x-axis. A particle of mass m and charge q_0=q/2 is placed at the origin. If charge q_0 is given a small displacement (ylt lt a) along the y-axis, the net force acting on the particle is proportional to

An electron is moving around infinite linear positive charge in the orbit of 0.1 m. If the linear charge density is 1 muC//m , the velocity of electron will be

.Does the velocity of all particles of a system is equal to the velocity of centre of mass?..

Imagine an atom made of a proton and a hypothetical particle of double the mass of the electron but having the same change as the electron. Apply the Bohr atom model and consider all possible transitions of this hypothetical particle of the first excited level. the longest wavelength photon that will be emitted has wavelength [given in terms of the Rydberg constant R for the hydrogen atom] equal to