Nuclear Feedback in a Single Electron-Charged Quantum Dot under Pulsed Optical Control
Abstract
Electron spins in quantum dots under coherent control exhibit a number of novel feedback processes. Here, we present experimental and theoretical evidence of a feedback process between nuclear spins and a single electron spin in a single charged InAs quantum dot, controlled by the coherently modified probability of exciting a trion state. We present a mathematical model describing competition between optical nuclear pumping and nuclear spin-diffusion inside the quantum dot. The model correctly postdicts the observation of a hysteretic sawtooth pattern in the free-induction-decay of the single electron spin, hysteresis while scanning a narrowband laser through the quantum dot's optical resonance frequency, and non-sinusoidal fringes in the spin echo. Both the coherent electron-spin rotations, implemented with off-resonant ultrafast laser pulses, and the resonant narrow-band optical pumping for spin initialization interspersed between ultrafast pulses, play a role in the observed behavior. This effect allows dynamic tuning of the electron Larmor frequency to a value determined by the pulse timing, potentially allowing more complex coherent control operations.
Cite
@article{arxiv.1008.0912,
title = {Nuclear Feedback in a Single Electron-Charged Quantum Dot under Pulsed Optical Control},
author = {Thaddeus D. Ladd and David Press and Kristiaan De Greve and Peter L. McMahon and Benedikt Friess and Christian Schneider and Martin Kamp and Sven Hoefling and Alfred Forchel and Yoshihisa Yamamoto},
journal= {arXiv preprint arXiv:1008.0912},
year = {2012}
}
Comments
15 pages, 7 figures. Corrected and expanded discussion. Now includes analysis of spin-echo and optical pumping experiments, in addition to FID