If an electron in hydrogen atom jumps from third orbit to second orbit, the Wavelength of the emitted radiation is given by (c is speed of light )

If an electron in hydrogen atom jumps from third orbit to second orbit, the frequency of the emitted radiation is given by (c is speed of light )

if the electron in hydrogen orbit jumps form third orbit to second orbit, the wavelength of the emitted radiation is given by

When the electron in hydrogen atom jumps from the second orbit to the first orbit, the wavelength of the radiation emitted is lambda . When the electron jumps from the third to the first orbit . The wavelenth of the radiation emitted is

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

If an electron in a hydrogen atom jumps from the 3rd orbit to the 2nd orbit, it emits a photon of wavelength lambda . When it jumps form the 4th orbit to the 3dr orbit, the corresponding wavelength of the photon will be

If, an electron in hydrogen atom jumps from an orbit of lelvel n=3 to an orbit of level n=2, emitted radiation has a freqwuency (R= Rydbertg's contant ,c = velocity of light)

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

Electron in hydrogen atom first jumps from third excited state to second excited state and then form second excited state to first excited state. The ratio of wavelength lambda_(1): lambda_(2) emitted in two cases is

If the electron in hydrogen atom jumps from second Bohr orbit to ground state and difference between energies of the two states is radiated in the form of photons. If the work function of the material is 4.2 eV , then stopping potential is [Energy of electron in nth orbit = - (13.6)/(n^(2)) eV ]