Searching strong `spin'-orbit coupled one-dimensional hole gas in strong magnetic fields

Abstract

We show that a strong `spin'-orbit coupled one-dimensional (1D) hole gas is achievable via applying a strong magnetic field to the original two-fold degenerate (spin degeneracy) hole gas confined in a cylindrical Ge nanowire. Both strong longitudinal and strong transverse magnetic fields are feasible to achieve this goal. Based on quasi-degenerate perturbation calculations, we show the induced low-energy subband dispersion of the hole gas can be written as E=2k2z/(2m*h)+ασzkz+g*hμBBσx/2, a form exactly the same as that of the electron gas in the conduction band. Here the Pauli matrices σz,x represent a pseudo spin (or `spin' ), because the real spin degree of freedom has been split off from the subband dispersions by the strong magnetic field. Also, for a moderate nanowire radius R=10 nm, the induced effective hole mass m*h (0.0650.08~me) and the `spin'-orbit coupling α (0.350.8 eV~) have a small magnetic field dependence in the studied magnetic field interval 1<B<15 T, while the effective g-factor g*h of the hole `spin' only has a small magnetic field dependence in the large field region.