Ambipolar spin diffusion and D'yakonov-Perel' spin relaxation in GaAs quantum wells

TL;DR

This paper investigates ambipolar spin diffusion in GaAs quantum wells, revealing two diffusion regimes and linking long-time spin relaxation behavior to Coulomb scattering effects described by D'yakonov-Perel' theory.

Contribution

It provides both experimental and theoretical insights into spin diffusion dynamics and the role of Coulomb scattering in spin relaxation in GaAs quantum wells.

Findings

Initial spin diffusion rate matches density diffusion controlled by ambipolar coefficient

Long-term spin diffusion slows down due to decreasing spin diffusion coefficient

Spin relaxation rate increases with decreasing density, consistent with D'yakonov-Perel' model

Abstract

We report theoretical and experimental studies of ambipolar spin diffusion in a semiconductor. A circularly polarized laser pulse is used to excite spin-polarized carriers in a GaAs multiple quantum well sample at 80 K. Diffusion of electron and spin densities is simultaneously measured using a spatially and temporally resolved pump-probe technique. Two regimes of diffusion for spin-polarized electrons are observed. Initially, the rate of spin diffusion is similar to that of density diffusion and is controlled by the ambipolar diffusion coefficient. At later times, the spin diffusion slows down considerably relative to the density diffusion and appears to be controlled by a non-constant (decreasing) spin diffusion coefficient. We suggest that the long-time behavior of the spin density can be understood in terms of an inhomogeneous spin relaxation rate, which grows with decreasing density. The behavior of the spin relaxation rate is consistent with a model of D'yakonov-Perel' relaxation limited by the Coulomb scattering between carriers.