The gravitational attraction between electron and proton in a hydrogen atom is weaker than the coulomb attraction by a factor of about `10^(-40)`. An alternative way of looking at this fact is to estimate the radius of the first Bohr orbit of a hydrogen atom if the electron and proton were bound by gravitational attraction. You will find the answer interesting.

The radius of the first orbit of electron in hydrogen atom (e=1.6xx10^(-19)" coulomb,

In the Bohr model of hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton the electro. If a_0 is the ground state orbit, m is the mass, e is the charge on the electron, in_0 is the vacuum perimittivity, then the speed or electron is

is found experimentally that 13.6 eV energy is required to separate a hydrogen atom into a proton and an electron. Compute the orbital radius and the velocity of the electron in a hydrogen atom.

In a hydrogen atom, the electron and proton are bound at a distance of about 0.53 Å (a) Estimate the potential energy of the system in eV, taking the zero of the potential energy at infinite separation of the electron from proton. (b) What is the minimum work required to free the electron, given that its kinetic energy in the orbit is half the magnitude of potential energy obtained in (a)? (c) What are the answers to (a) and (b) above if the zero of potential energy is taken at 1.06 Å separation?

In a Bohr model of hydrogen atom, the electron circulates around the nucleus in the path of radius 5.1 xx 10^-11m at a frequency of 6.8 xx 10^15 rev//s . Calculate the magnetic Induction B at the centre of the orbit. What is the equivalent dipole moment ?