Semiclassical kinetic theory of electron spin relaxation in semiconductors

TL;DR

This paper develops a semiclassical kinetic theory for electron spin relaxation in semiconductors, incorporating various scattering processes and deriving a Bloch equation to predict spin lifetimes under different conditions.

Contribution

It introduces a unified approach that treats multiple spin relaxation mechanisms on equal footing and derives a long-time Bloch equation from quantum kinetic equations.

Findings

Spin lifetimes are non-monotonic with temperature and density.

Longer spin lifetimes occur near the degenerate regime transition.

The theory provides an intuitive framework for spin dynamics analysis.

Abstract

We develop a semiclassical kinetic theory for electron spin relaxation in semiconductors. Our approach accounts for elastic as well as inelastic scattering and treats Elliott-Yafet and motional-narrowing processes, such as D'yakonov-Perel' and variable g-factor processes, on an equal footing. Focusing on small spin polarizations and small momentum transfer scattering, we derive, starting from the full quantum kinetic equations, a Fokker-Planck equation for the electron spin polarization. We then construct, using a rigorous multiple time scale approach, a Bloch equation for the macroscopic ($\vec{k}$-averaged) spin polarization on the long time scale, where the spin polarization decays. Spin-conserving energy relaxation and diffusion, which occur on a fast time scale, after the initial spin polarization has been injected, are incorporated and shown to give rise to a weight function which defines the energy averages required for the calculation of the spin relaxation tensor in the Bloch equation. Our approach provides an intuitive way to conceptualize the dynamics of the spin polarization in terms of a ``test'' spin polarization which scatters off ``field'' particles (electrons, impurities, phonons). To illustrate our approach, we calculate for a quantum well the spin lifetime at temperatures and densities where electron-electron and electron-impurity scattering dominate. The spin lifetimes are non-monotonic functions of temperature and density. Our results show that at electron densities and temperatures, where the cross-over from the non-degenerate to the degenerate regime occurs, spin lifetimes are particularly long.