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 the wave length of the first member of Balmer series of a hydrogen atom is 6300Å, that of the second member will be nearly

If the wave number of 1^(st) line of Balmer series of H-atom is 'x' then :

Using Bohr's postulates, derive the expression for the total energy of the electron revolving in n^(th) orbit of hydrogen atom. Find the wavelength of H_(alpha) line, given the value of Rydberg constant, R = 1.1 xx 10^(7) m^(1)

The wavelength of the first line of Balmer series is 6563 Å . The Rydberg's constant for hydrogen is about

The wavelength of the first line of Balmer series is 6563 Å . The Rydbergs constant for hydrogen is about

The electon, in a hydrogen atom, is in its second excited state. Calculate the wavelength of the lines in the Lyman series, that can be emitted through the permisible transitions of this electron. Given the value of Rydberg constant, R=1.1xx10^(7)m^(-1))

The wave number of first line of Balmer series of hydrogen is 1520m^(-1) . The wave number of first Balmer line of Li^(2+) ion in m^(-1) is x. Find the vlaue of (x)/(100) .

The wavelength of the first line of Lyman series in hydrogen atom is 1216 . The wavelength of the first line of Lyman series for 10 times ionized sodium atom will be added

The wavelength of the first line of Lyman series in hydrogen atom is 1216 . The wavelength of the first line of Lyman series for 10 times ionized sodium atom will be added

The wave number of the first emission line in the Balmer series of H - Spectrum is (n)/(36)R . The value of 'n' is. (R = Rydberg constant):