Direct mapping of the formation of a persistent spin helix: Supplementary information

TL;DR

This paper demonstrates direct, time- and space-resolved imaging of the formation of a persistent spin helix in semiconductor quantum wells, revealing how external magnetic fields influence its stability and spin lifetime.

Contribution

It provides the first direct observation and mapping of the formation of a persistent spin helix using a magneto-optical Kerr rotation technique, including experimental determination of SOI parameters.

Findings

Direct visualization of spin helix formation

Magnetic field effects on spin lifetime and symmetry

Experimental confirmation of SOI parameters

Abstract

The spin-orbit interaction (SOI) in zincblende semiconductor quantum wells can be set to a symmetry point, in which spin decay is strongly suppressed for a helical spin mode. Signatures of such a persistent spin helix (PSH) have been probed using the transient spin grating technique, but it has not yet been possible to observe the formation and the helical nature of a PSH. Here we directly map the diffusive evolution of a local spin excitation into a helical spin mode by a time- and spatially resolved magneto-optical Kerr rotation technique. Depending on its in-plane direction, an external magnetic field interacts differently with the spin mode and either highlights its helical nature or destroys the SU(2) symmetry of the SOI and thus decreases the spin lifetime. All relevant SOI parameters are experimentally determined and confirmed with a numerical simulation of spin diffusion in the presence of SOI.