Spin Relaxation in Quantum Wires

TL;DR

This paper reviews spin relaxation mechanisms in quantum wires with spin-orbit coupling, highlighting the reduction of relaxation rates in narrow wires and discussing experimental and theoretical challenges.

Contribution

It provides a comprehensive review of spin relaxation in quantum wires, deriving solutions for the spin diffusion equation and connecting theoretical predictions with experimental findings.

Findings

Spin relaxation rate decreases in wires narrower than the spin precession length.

Experimental evidence shows a crossover from weak antilocalization to weak localization.

Open problems include contrasting behaviors in ballistic wires.

Abstract

The spin dynamics and spin relaxation of itinerant electrons in quantum wires with spin-orbit coupling is reviewed. We give an introduction to spin dynamics, and review spin-orbit coupling mechanisms in semiconductors. The spin diffusion equation with spin-orbit coupling is derived, using only intuitive, classical random walk arguments. We give an overview of all spin relaxation mechanisms, with particular emphasis on the motional narrowing mechanism in disordered conductors, the D'yakonov-Perel'-Spin relaxation. Here, we discuss in particular, the existence of persistent spin helix solutions of the spin diffusion equation, with vanishing spin relaxation rates. We then, derive solutions of the spin diffusion equation in quantum wires, and show that there is an effective alignment of the spin-orbit field in wires whose width is smaller than the spin precession length $L_{\rm SO}$. We show that the resulting reduction in the spin relaxation rate results in a change in the sign of the quantum corrections to the conductivity. Finally, we present recent experimental results which confirm the decrease of the spin relaxation rate in wires whose width is smaller than $L_{\rm SO}$: the direct optical measurement of the spin relaxation rate, as well as transport measurements, which show a dimensional crossover from weak antilocalization to weak localization as the wire width is reduced. Open problems remain, in particular in narrower, ballistic wires, were optical and transport measurements seem to find opposite behavior of the spin relaxation rate: enhancement, suppression, respectively. We conclude with a review of these and other open problems which still challenge the theoretical understanding and modeling of the experimental results.