Single-electron entanglement and nonlocality
Abstract
Motivated by recent progress in electron quantum optics, we revisit the question of single-electron entanglement, specifically whether the state of a single electron in a superposition of two separate spatial modes should be considered entangled. We first discuss a gedanken experiment with single-electron sources and detectors, and demonstrate deterministic (i. e. without post-selection) Bell inequality violation. This implies that the single-electron state is indeed entangled and, furthermore, nonlocal. We then present an experimental scheme where single-electron entanglement can be observed via measurements of the average currents and zero-frequency current cross-correlators in an electronic Hanbury Brown-Twiss interferometer driven by Lorentzian voltage pulses. We show that single-electron entanglement is detectable under realistic operating conditions. Our work settles the question of single-electron entanglement and opens promising perspectives for future experiments.
Cite
@article{arxiv.1511.04450,
title = {Single-electron entanglement and nonlocality},
author = {David Dasenbrook and Joseph Bowles and Jonatan Bohr Brask and Patrick P. Hofer and Christian Flindt and Nicolas Brunner},
journal= {arXiv preprint arXiv:1511.04450},
year = {2016}
}
Comments
15 pages, 2 figures