Spin-Orbit Coupling in Diamond and Zincblende Heterostructures

TL;DR

This paper develops a comprehensive group theory-based framework to understand spin splittings in diamond and zincblende heterostructures, highlighting the roles of crystal symmetry and confinement effects in spintronic applications.

Contribution

It introduces a general theoretical approach to analyze spin splittings in heterostructures, emphasizing the interplay of crystal symmetry and confinement without relying solely on potential asymmetry.

Findings

Spin splittings depend on crystal symmetry and confinement effects.

Both Dresselhaus and Rashba contributions are significant in asymmetric wells.

Confinement enhances spin splittings even with symmetric potentials.

Abstract

Spin splittings in III-V materials and heterostructures are of interest because of potential applications, mainly in spintronic devices. A necessary condition for the existence of these spin splittings is the absence of inversion symmetry. In bulk zincblende materials the inversion symmetry is broken, giving rise to a small spin splitting. The much larger spin splitting observed in quantum wells is normally attributed to the asymmetry of the confining potential and explained on the basis of the Rashba effect. For symmetrically confined wells, where the only source of asymmetry is that of the underlying crystal potential, the confining potential strongly enhances the spin splittings. This enhancement does not require the asymmetry of the confining potential but depends on the interplay between the confinement and the crystal potential. In this situation the behavior of the spin splittings is consistent with the Dresselhaus contribution. In asymmetrically confined wells both Dresselhaus and Rashba terms contribute. We present a general theory of the spin splittings of these structures based on the group theory of diamond and zincblende heterostructures.