The Zeeman, Spin-Orbit, and Quantum Spin-Hall Interactions in Anisotropic and Low-Dimensional Conductors

Abstract

When an electron or hole is in a conduction band of a crystal, it can be very different from 2, depending upon the crystalline anisotropy and the direction of the applied magnetic induction B. In fact, it can even be 0! To demonstrate this quantitatively, the Dirac equation is extended for a relativistic electron or hole in an orthorhombically-anisotropic conduction band with effective masses mj for j=1,2,3 with geometric mean mg=(m1m2m3)1/3. The appropriate Foldy-Wouthuysen transformations are extended to evaluate the non-relativistic Hamiltonian to O( mc2)-4, where mc2 is the particle's Einstein rest energy. For B|| eμ, the Zeeman gμ factor is 2 mmμ/mg3/2 + O( mc2)-2. While propagating in a two-dimensional (2D) conduction band with m3 m1,m2, g||<<2, consistent with recent measurements of the temperature T dependence of the parallel upper critical induction Bc2,||(T) in superconducting monolayer NbSe2 and in twisted bilayer graphene. While a particle is in its conduction band of an atomically thin one-dimensional metallic chain along eμ, g<<2 for all B=∇× A directions and vanishingly small for B|| eμ. The quantum spin Hall Hamiltonian for 2D metals with m1=m2=m|| is K[ E×( p-q A)]σ+O( mc2)-4, where E and p-q A are the planar electric field and gauge-invariant momentum, q=|e| is the particle's charge, σ is the Pauli matrix normal to the layer, K=μB/(2m||c2), and μB is the Bohr magneton.