English

Stretchable persistent spin helices in GaAs quantum wells

Mesoscale and Nanoscale Physics 2017-07-26 v2

Abstract

The Rashba and Dresselhaus spin-orbit (SO) interactions in 2D electron gases act as effective magnetic fields with momentum-dependent directions, which cause spin decay as the spins undergo arbitrary precessions about these randomly-oriented SO fields due to momentum scattering. Theoretically and experimentally, it has been established that by fine-tuning the Rashba α\alpha and Dresselhaus β\beta couplings to equal fixed\it{fixed} strengths α=β\alpha=\beta, the total SO field becomes unidirectional thus rendering the electron spins immune to dephasing due to momentum scattering. A robust persistent spin helix (PSH) has already been experimentally realized at this singular point α=β\alpha=\beta. Here we employ the suppression of weak antilocalization as a sensitive detector for matched SO fields together with a technique that allows for independent electrical control over the SO couplings via top gate voltage VTV_T and back gate voltage VBV_B. We demonstrate for the first time the gate control of β\beta and the continuouslocking\it{continuous\,locking} of the SO fields at α=β\alpha=\beta, i.e., we are able to vary both α\alpha and β\beta controllably and continuously with VTV_T and VBV_B, while keeping them locked at equal strengths. This makes possible a new concept: "stretchable PSHs", i.e., helical spin patterns with continuously variable pitches PP over a wide parameter range. The extracted spin-diffusion lengths and decay times as a function of α/β\alpha/\beta show a significant enhancement near α/β=1\alpha/\beta=1. Since within the continuous-locking regime quantum transport is diffusive (2D) for charge while ballistic (1D) for spin and thus amenable to coherent spin control, stretchable PSHs could provide the platform for the much heralded long-distance communication 825\sim 8 - 25 μ\mum between solid-state spin qubits.

Keywords

Cite

@article{arxiv.1702.05190,
  title  = {Stretchable persistent spin helices in GaAs quantum wells},
  author = {Florian Dettwiler and Jiyong Fu and Shawn Mack and Pirmin J. Weigele and J. Carlos Egues and David D. Awschalom and Dominik M. Zumbühl},
  journal= {arXiv preprint arXiv:1702.05190},
  year   = {2017}
}

Comments

5 color figures, with supplementary info available on arXiv. arXiv admin note: substantial text overlap with arXiv:1403.3518

R2 v1 2026-06-22T18:20:48.691Z