Nonclassical Light from Exciton Interactions in a Two-Dimensional Quantum Mirror
Abstract
Excitons in a semiconductor monolayer form a collective resonance that can reflect resonant light with extraordinarily high efficiency. Here, we investigate the nonlinear optical properties of such atomistically thin mirrors and show that finite-range interactions between excitons can lead to the generation of highly non-classical light. We describe two scenarios, in which optical nonlinearities arise either from direct photon coupling to excitons in excited Rydberg states or from resonant two-photon excitation of Rydberg excitons with finite-range interactions. The latter case yields conditions of electromagnetically induced transparency and thereby provides an efficient mechanism for single-photon switching between high transmission and reflectance of the monolayer, with a tunable dynamical timescale of the emerging photon-photon interactions. Remarkably, it turns out that the resulting high degree of photon correlations remains virtually unaffected by Rydberg-state decoherence, in excess of non-radiative decoherence observed for ground-state excitons in two-dimensional semiconductors. This robustness to imperfections suggests a promising new approach to quantum photonics at the level of individual photons.
Keywords
Cite
@article{arxiv.2102.10350,
title = {Nonclassical Light from Exciton Interactions in a Two-Dimensional Quantum Mirror},
author = {Valentin Walther and Lida Zhang and Susanne F. Yelin and Thomas Pohl},
journal= {arXiv preprint arXiv:2102.10350},
year = {2022}
}
Comments
11 pages, 7 figures