English

A chiral one-dimensional atom using a quantum dot in an open microcavity

Quantum Physics 2022-10-26 v1 Optics

Abstract

In nanostructures, the light-matter interaction can be engineered to be chiral. In the fully quantum regime, a chiral one-dimensional atom, a photon propagating in one direction interacts with the atom; a photon propagating in the other direction does not. Chiral quantum optics has applications in creating nanoscopic single-photon routers, circulators, phase-shifters and two-photon gates. Furthermore, the directional photon-exchange between many emitters in a chiral system may enable the creation of highly exotic quantum states. Here, we present a new way of implementing chiral quantum optics - we use a low-noise quantum dot in an open microcavity. Specifically, we demonstrate the non-reciprocal absorption of single photons, a single-photon diode. The non-reciprocity, the ratio of the transmission in the forward-direction to the transmission in the reverse direction, is as high as 10.7 dB, and is optimised in situ\textit{in situ} by tuning the photon-emitter coupling to the optimal operating condition (β=0.5\beta = 0.5). Proof that the non-reciprocity arises from a single quantum emitter lies in the nonlinearity with increasing input laser power, and in the photon statistics - ultralow-power laser light propagating in the diode's reverse direction results in a highly bunched output (g(2)(0)=101g^{(2)}(0) = 101), showing that the single-photon component is largely removed. The results pave the way to a single-photon phase shifter, and, by exploiting a quantum dot spin, to two-photon gates and quantum non-demolition single-photon detectors.

Keywords

Cite

@article{arxiv.2110.02650,
  title  = {A chiral one-dimensional atom using a quantum dot in an open microcavity},
  author = {Nadia O. Antoniadis and Natasha Tomm and Tomasz Jakubczyk and Rüdiger Schott and Sascha R. Valentin and Andreas D. Wieck and Arne Ludwig and Richard J. Warburton and Alisa Javadi},
  journal= {arXiv preprint arXiv:2110.02650},
  year   = {2022}
}
R2 v1 2026-06-24T06:39:54.350Z