Emission transition in the Paschen series end at orbit n=3 and start from orbit n and can be represented as `v=3.29 xx 10^(15) (Hz) [1//3^2-1//n^2]`
Calculate the value of n if the transition is observed at 1285nm Find the region of the spectrum.

Emission transitions in the Paschen series end at orbit n=3 and start from orbit n and can be represented as v=3.29xx10^(15) (Hz)[1//3^(2)-1//n^(2)] Calculate the value of n if the transition is observed at 1285 nm . Find the region of the spectrum.

Calculate the wavelength for the emission transition if it starts from the orbit having radius 1.3225 nm ends at 211.6 p m . Name the series to which this transition belongs and the region of the spectrum.

The Lyman series of the hydrogen spectrum can be represented by the equation v = 3.2881 xx 10^(15)s^(-1)[(1)/((1)^(2)) - (1)/((n)^(2))] [where n = 2,3,…….) Calculate the maximum and minimum frequencies of the lines in this series

The transition of electron from n = 3 to n = 1 in H atom produces

If "^(2n+1)P_(n-1):^(2n-1)P_n=3:5, then find the value of n .

For the Paschen series thr values of n_(1) and n_(2) in the expression Delta E = R_(H)c [(1)/(n_(1)^(2))-(1)/(n_(2)^(2))] are

Why is the transition from n=3 to n=1 gives a spectral triplet

Calculate the wavelength of a photon emitted when an electron in H- atom maker a transition from n=2 to n=1

Calculate the change in magnetic dipole moment when the electron in a H- atom makes a transition from the n=4 orbit to the n=3 orbit. Suppose that the atoms is in a magnetic field of induction. Calculate the change in energy when it makes the same transition and the corresponding change in frequency of the emitted photon due to the magnetic field.

The Balmer series in the hydrogen spectrum corresponds to the transition from n_(1)=2 to n_(2)=3,4 ........ This series lies in the visible region. Calculate the wave number of line associated with the transition in Balmer series when the electron moves to n=4 orbit. (R_(H)=109677cm^(-1))