Hyperfine-changing transitions in 3He II and other one-electron ions by electron scattering

Abstract

We consider the spin-exchange (SE) cross section in electron scattering from 3He\, II, which drives the hyperfine-changing 3.46 cm (8.665 GHz) line transition. Both the analytical quantum defect method --- applicable at very low energies --- and accurate R-matrix techniques for electron-He+ scattering are employed to obtain SE cross sections. The quantum defect theory is also applied to electron collisions with other one-electron ions in order to demonstrate the utility of the method and derive scaling relations. At very low energies, the hyperfine-changing cross sections due to e-He+ scattering are much larger in magnitude than for electron collisions with neutral hydrogen, hinting at large rate constants for equilibration. Specifically, we obtain rate coefficients of K(10\, K) = 1.10 × 10-6\, cm3/s and K(100\, K) = 3.49× 10-7\, cm3/s.