An electron in a hydrogen like species makes a transition from the nth Bohr orbit to the next outer Bohr `(n + 1)` .Find an approximate relation between the dependence of the frequency of the photon absorbed as a function of n .Assume n its to have a large value `(ngt gt1)`

The electron in a hydrogen atom at rest makes a transition from n = 2 energy state to the n = 1 ground state. find the energy (eV) of the emitted photon.

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

In a hydrogen like atom electron make transition from an energy level with quantum number n to another with quantum number (n - 1) if n gtgt1 , the frequency of radiation emitted is proportional to :

An electron in hydrogen-like atom makes a transition from nth orbit or emits radiation corresponding to Lyman series. If de Broglie wavelength of electron in nth orbit is equal to the wavelength of rediation emitted , find the value of n . The atomic number of atomis 11 .

An electron in a hydrogen atom makes a transition from n_(1) to n_(2) . If the time period of electron in the initial state is eight times that in the final state then Find the ratio n_(1)/n_(2)

In a hydrogen atom the electron makes a transition from (n+1)^(th) level to the n^(th) level .If n gt gt 1 the frequency of radiation emitted is proportional to :

In a hydrogen atom , the electron atom makes a transition from n = 2 to n = 1 . The magnetic field produced by the circulating electron at the nucleus

When an electron makes a transition from (n+1) state of nth state, the frequency of emitted radiations is related to n according to (n gtgt 1) :

When an electron makes a transition from (n + 1) state to n state the frequency of emitted radiation is related to n according to (n gtgt 1)

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.