When an electron makes transition from its stable orbit to another stable orbit of lower energy , where does the remaining energy go ?

S_(1) : Potential energy of the two opposite charge system increase with the decrease in distance . S_(2) : When an electron makes transition from higher orbit to lower orbit it's kinetic energy increases. S_(3) : When an electron make transition from lower energy to higher energy state its potential energy increases. S_(4) : 11 eV photon can free an electron from 1 st excited state of He^(+) ion . Select the correct set of true-false for above statements.

when an electron jumps from the fourth orbit to the second orbit, one gets the

when an electron jumps from the fourth orbit to the second orbit, one gets the

The frequency of revolution of an electron in nth orbit is f_(n) . If the electron makes a transition from nth orbit to (n = 1) th orbit , then the relation between the frequency (v) of emitted photon and f_(n) will be

An electron makes a transition from orbit n = 4 to the orbit n = 2 of a hydrogen atom. The wave number of the emitted radiations (R = Rydberg's constant) will be

An electron makes a transition from orbit n = 4 to the orbit n = 2 of a hydrogen atom. The wave length of the emitted radiations (R = Rydberg's constant) will be

Calculate the change in magnetic dipole moment when the electron in a H- atom makes a transition from the n=4 orbit to the n=3 orbit. Suppose that the atoms is in a magnetic field of induction. Calculate the change in energy when it makes the same transition and the corresponding change in frequency of the emitted photon due to the magnetic field.

When electronic transition occurs from higher energy state to lower energy state with energy difference equal to Delta E electron volts , the wavelength of the line emitted is approximately equal to

When electronic transition occurs from higher energy state to lower energy state with energy difference equal to Delta E electron volts , the wavelength of the line emitted is approxmately equal to

When an electron jumps from n_(1) th orbit to n_(2) th orbit, the energy radiated is given by