Controlling the persistent spin helix with strain induced spin-orbit coupling

Luyi Yang; Jake Koralek; J. Orenstein; Andrei Bernevig; Shoucheng Zhang; Shawn Mack; David Awschalom

Controlling the persistent spin helix with strain induced spin-orbit coupling

ORAL

Abstract

We use transient spin grating spectroscopy to study the persistent spin helix (PSH) state of the 2D electron gas. The PSH is a meta-stable helical spin density wave that emerges as a result of increased symmetry when the Rashba and Dresselhaus spin-orbit coupling terms are balanced, and which offers great promise as a means of controlling large ensembles of spins. We demonstrate that the spin-orbit symmetry, and the PSH dynamics, can be manipulated \textit{in-situ} by the application of uniaxial strain. This strain induces spin-orbit coupling with precisely the same symmetry as the Rashba term, allowing us to effectively tune the Rashba/Dresselhaus ratio in a single sample. This work is supported by DMSE office of BES-DOE, NSF, MARCO, ASEE and CNID.

March 17, 2009, 4:42 PM – March 17, 2009, 4:54 PM

Authors

Luyi Yang
- Lawrence Berkeley National Laboratory and University of California Berkeley
Jake Koralek
- Lawrence Berkeley National Laboratory
J. Orenstein
- Lawrence Berkeley National Laboratory and University of California Berkeley
Andrei Bernevig
- Princeton University
Shoucheng Zhang
- Stanford University
Shawn Mack
- Center for Spintronics and Quantum Computation, University of California Santa Barbara
David Awschalom
- Center for Spintronics and Quantum Computation, University of California Santa Barbara