Noble-gas atoms characterized by hyperfine frequency shift of lithium atom

Abstract: We report an experimental and theoretical study on the shift of the hyperfine splitting frequency of ground-state Li atoms in noble gases, He, Ne, Ar, and Xe. The frequency shift is due to the change in the electron-spin density at the Li nuclei induced by collisions to the noble-gas atoms. The electron density is calculated along the interatomic distance in a pseudopotential and a dispersion potential. Based on the measured and the calculated frequency shifts, we find the importance of attractive force in col… Show more

“…It is the dominant spin interaction responsible for the linear pressure shift. [7][8][9] The potential δ A(R) is generally expected to change sign at least once at small R for our molecules of interest. 8,9,35,37,[51][52][53][54][55][56][57][58] As a result, the sign of the fitting parameters for binary and molecular shifts need not agree.…”

“…[3][4][5][6] In these devices, collisions with the gas shift the resonant frequencies ν away from their free-atom values ν 0 by an amount, ν − ν 0 , that depends on the gas composition, pressure, and temperature. Known as the "pressure" shift, [7][8][9][10] these shifts are very nearly linear with the buffer-gas pressure p at typical partial-vacuum cell pressures. Fig.…”

Isotope study of the nonlinear pressure shifts of $^{85}$Rb and $^{87}$Rb hyperfine resonances in Ar, Kr, and Xe buffer gases

“…It is the dominant spin interaction responsible for the linear pressure shift. [7][8][9] The potential δ A(R) is generally expected to change sign at least once at small R for our molecules of interest. 8,9,35,37,[51][52][53][54][55][56][57][58] As a result, the sign of the fitting parameters for binary and molecular shifts need not agree.…”

“…[3][4][5][6] In these devices, collisions with the gas shift the resonant frequencies ν away from their free-atom values ν 0 by an amount, ν − ν 0 , that depends on the gas composition, pressure, and temperature. Known as the "pressure" shift, [7][8][9][10] these shifts are very nearly linear with the buffer-gas pressure p at typical partial-vacuum cell pressures. Fig.…”

Isotope study of the nonlinear pressure shifts of $^{85}$Rb and $^{87}$Rb hyperfine resonances in Ar, Kr, and Xe buffer gases

Ground-state decoherence of lithium atoms by diatomic polar molecules and noble-gas atoms

Collisional shifts of hyperfine resonances of ground-state atoms calculated with modified pseudopotential and orthogonalization