Hyperfine structure

In atomic physics, hyperfine structure is a small perturbation in the energy levels (or spectrum) of atoms or molecules due to the magnetic dipole-dipole interaction, arising from the interaction of the nuclear magnetic dipole with the magnetic field of the electron.

According to classical thinking, the electron moving around the nucleus has a magnetic dipole moment, because it is charged. The interaction of this magnetic dipole moment with the magnetic moment of the nucleus (due to its spin) leads to hyperfine splitting.

However, due to the electron's spin, there is also hyperfine splitting for s-shell electrons, which have zero orbital angular momentum. In this case, the magnetic dipole interaction is even stronger, as the electron probability density does not vanish inside the nucleus (${\displaystyle r=0}$).

The amount of correction to the Bohr energy levels due to hyperfine splitting of the hydrogen atom is on the order of:

${\displaystyle {\frac {m}{m_{p}}}\alpha ^{4}mc^{2}}$

where

m is the mass of an electron

m_p is the mass of a proton

α is the fine structure constant (1/137.036)

c is the speed of light.

For atoms other than hydrogen, the nuclear spin ${\displaystyle {\vec {I}}}$ and the total electron angular momentum ${\displaystyle {\vec {J}}={\vec {L}}+{\vec {S}}}$ get coupled, giving rise to the total angular momentum ${\displaystyle {\vec {F}}={\vec {J}}+{\vec {I}}}$. The hyperfine splitting is then

${\displaystyle \Delta E_{hfs}=-{\vec {\mu }}_{I}{\vec {B}}_{J}={\frac {a}{2}}[F(F+1)-I(I+1)-J(J+1)],}$

where

${\displaystyle a={\frac {g_{I}{\vec {\mu }}_{N}{\vec {B}}_{J}}{\sqrt {J(J+1)}}},}$

with ${\displaystyle {\vec {\mu }}_{N}}$ the magnetic dipole moment of the nucleus.

This interaction obeys the Lande interval rule: The energy level is split into ${\displaystyle (J+I)-|J-I|+1}$ energy levels, where ${\displaystyle J}$ denotes the total electron angular momentum and ${\displaystyle I}$ denotes the nuclear spin.

With ${\displaystyle \Delta E_{hfs}\approx \hbar }$, the hyperfine splitting is a much smaller perturbation than the fine structure.

In a more advanced treatment, one also has to take the nuclear magnetic quadrupole moment into account. This is sometimes (?) refered to as "hyperfine structure anomaly".

The optical hyperfine structure was already observed in 1881 by Albert Abraham Michelson. It could, however, only be explained in terms of quantum mechanics in the 1920s. Wolfgang Pauli proposed the existence of a small nuclear magnetic moment in 1924.

In 1935, M. Schiiler and T. Schmidt proposed the existence of a nuclear quadrupole moment in order to explain anomalies in the hyperfine structure.

As the hyperfine splitting is very small, the transition frequencies usually are not optical, but in the range of radio- or microwave frequencies.

Hyperfine structure gives the 21 cm line observed in HI region in interstellar medium.

Carl Sagan and Frank Drake considered the hyperfine transition of hydrogen to be a sufficiently universal phenomenon so as to be used as a base unit of time and length on the Pioneer plaque and later Voyager Golden Record.

The AVLIS and MLIS processes use hyperfine splitting caused by differences between the mass of atomic nucleus for uranium-235 and uranium-238 to selectively photoionize only the uranium-235 atoms and then separate the ionized particles from the non-ionized ones. Precisely tuned dye lasers are used as the sources of the necessary exact wavelength radiation.

The hyperfine structure transition can be used to make a microwave notch filter with very high stability, repeatability and Q factor, which can thus be used as a basis for very precise atomic clocks. Typically, the hyperfine structure transition frequency of a particular isotope of caesium or rubidium atoms is used as a basis for these clocks.

Due to the accuracy of hyperfine structure transition-based atomic clocks, they are now used as the basis for the definition of the second. One second is now defined to be exactly 9,192,631,770 cycles of the hyperfine structure transition frequency of caesium-133 atoms.

Since 1983, the meter is defined by declaring the speed of light in a vacuum to be exactly 299,792,458 metres per second. Thus:

The metre is the length of the path travelled by light in vacuum during a time interval of 1/299 792 458 of a second.

• Energy levels