In the process of solving the Schrodinger equation for the hydrogen atom, it is found that the orbital angular momentum is quantized according to the relationship:
It is a characteristic of angular momenta in quantum mechanics that the magnitude of the angular momentum in terms of the orbital quantum number is of the form
and that the z-component of the angular momentum in terms of the magnetic quantum number takes the form
The orbital angular momentum of electrons in atoms associated with a given quantum state is found to be quantized in the form
This is the result of applying quantum theory to the orbit of the electron. The solution of the Schrodinger equation yields the angular momentum quantum number. Even in the case of the classical angular momentum of a particle in orbit,
the angular momentum is conserved. The Bohr theory proposed the quantization of the angular momentum in the form
and the subsequent application of the Schrodinger equation confirmed that form for the orbital angular momentum.
The spectroscopic notation used for characterizing energy levels of atomic electrons is based upon the orbital quantum number.
When the orbital angular momentum and spin angular momentum are coupled, the total angular momentum is of the general form for quantized angular momentum
where the total angular momentum quantum number is
This gives a z-component of angular momentum
This kind of coupling gives an even number of angular momentum levels, which is consistent with the multiplets seen in anomalous Zeeman effects such as that of sodium.
As long as external interactions are not extremely strong, the total angular momentum of an electron can be considered to be conserved and j is said to be a "good quantum number". This quantum number is used to characterize the splitting of atomic energy levels, such as the spin-orbit splitting which leads to the sodium doublet.
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