The energy of `n^(th)` orbit is given by
`E_(n) = ( -Rhc)/(n^(2))`
When electron jumpsfrom one orbit to another orbit then wavelength associated with the radiation is given by
`(1)/(lambda) = RZ^(2)((1)/(n_(1)^(2)) - (1)/ (n_(2)^(2)))`
The series that belongs to visible region is

The energy of n^(th) orbit is given by E_(n) = ( -Rhc)/(n^(2)) When electron jumpsfrom one orbit to another orbit then wavelength associated with the radiation is given by (1)/(lambda) = RZ^(2)((1)/(n_(1)^(2)) - (1)/ (n_(2)^(2))) When electron of 1.0 gm atom of Hydrogen undergoes transition giving the spectral line of lowest energy is visible region of its atomic spectra, the wavelength of radiation is

The energy of n^(th) orbit is given by E_(n) = ( -Rhc)/(n^(2)) When electron jumps from one orbit to another orbit then wavelength associated with the radiation is given by (1)/(lambda) = RZ^(2)((1)/(n_(1)^(2)) - (1)/ (n_(2)^(2))) The ratio of wavelength H_(alpha) of Lyman Series and H_(alpha) of Pfund Series is

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

When an electron jumps from the initial orbit n_(i) to the final orbit n_(f) , the energy radiated is given by

When an electron jumps from the orbit n=2 to n=4, then wavelength of the radiations absorbed will be where, (where R is Rydberg's constant)

The angular momentum of electron in n^(th) orbit is given by

The angular momentum of an electron in n^(th) orbit is given by

The energy of electron in the nth orbit of hydrogen atom is expressed as E_(n) = (-13.6)/(n^(2))eV . The shortest and longest wavelength of Lyman series will be

An electron changes its position from orbit n = 4 to the orbit n = 2 of an atom. The wavelength of the emitted radiation's is (R = Rydberg's constant)

Find the sum to n term of the series whose n^(th) term is given by n(n^(2) + 1)