If the wavelength of the first line of the Blamer series of hydrogen atom is `6561Å` , the wavelength of the second line of the series should be
a.13122Å b.3280Å c.4860Å d.2187Å

If the wavelength of the first line of the Balmer series of hydrogen is 6561 Å , the wavelngth of the second line of the series should be

If the wavelength of the first line of the Balmer series of hydrogen is 6561 Å , the wavelngth of the second line of the series should be

If the wavelength of the first member of Balmer series of hydrogen spectrum is 6563Å , then the wavelength of second member of Balmer series will be

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

The wavelength of the first spectral line in the Balmer series of hydrogen atom is 6561 A^(@) . The wavelength of the second spectral line in the Balmer series of singly - ionized helium atom is

The wavelength of first line of Balmer series is 6563Å . The wavelength of first line of Lyman series will be

the wavelength of the first line of lyman series is 1215 Å , the wavelength of first line of balmer series will be

The wavelength of first member of Balmer series is 6563 Å . Calculate the wavelength of second member of Lyman series.

In H–spectrum wavelength of 1^(st) line of Balmer series is lambda= 6561Å . Find out wavelength of 2^(nd) line of same series in nm.

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