Resonant spin polarization and spin current in a two-dimensional electron gas

TL;DR

This paper investigates how to enhance resonant spin polarization in disordered two-dimensional electron gases by optimizing field configurations, revealing a significant increase in spin susceptibility while suppressing the spin-Hall current.

Contribution

It introduces a method to reduce disorder damping of spin polarization through interference of Rashba and Dresselhaus interactions, leading to enhanced spin response.

Findings

Disorder damping can be minimized with optimal field configurations.

Spin susceptibility is significantly enhanced under these conditions.

Spin-Hall current can be suppressed while maintaining high spin polarization.

Abstract

We study the spin polarization and its associated spin-Hall current due to EDSR in disordered two-dimensional electron systems. We show that the disorder induced damping of the resonant spin polarization can be strongly reduced by an optimal field configuration that exploits the interference between Rashba and Dresselhaus spin-orbit interaction. This leads to a striking enhancement of the spin susceptibility while the spin-Hall current vanishes at the same time. We give an interpretation of the spin current in geometrical terms which are associated with the trajectories the polarization describes in spin space.