The wavelength of the radiation emitted when in hydrogen atom electron falls from infinity to second state Would be (Rydberg constant `1.097 xx 10^(7) m^(-1)`).

The wavelength of the radiation emitted, when in hydrogen atom electrons falls from infinity to stationary state 1, would be (Rydberg constant 1.097 xx 10^(7) m^(-1) )

The wavelength of the radiation emitted, when in hydrogen atom electron falls from infinity to stationary state 1, would be ("Rydberg constant "1.097 xx 10^(7) m^(-1))

The wavelength of the radiation emitted, when in hydrogen atom electron falls from 4 to stationary state 1, would be (Rydberg constant 1.097 xx 10^(7) m^(-1) )

The wavelength of a spectral line emitted by hydrogen atom in the Lyman series is 16/15R cm. The value of n_(2) if R is Rydberg constant

The wavelength of spectral line emitted by hydrogen atom in the Lyman series is (16)/(15R) cm. What is the value of n_2 ?(R-Rydberg constant)

The wave length of first member of Balmer series of a hydrogen atom is nearly (The value of Rydberg constant R = 1.08 xx 10^(7)m^(-1) )

If lamda_(1)andlamda_(2) are the wavelength of the photons emitted, when electrons in the n^(th) orbit of hydrogen atom fall to first excited state and ground state respectively, then the value of n is

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