Efficient quadrature-squeezing from biexcitonic parametric gain in atomically thin semiconductors
Abstract
Modification of electromagnetic quantum fluctuations in the form of quadrature-squeezing is a central quantum resource, which can be generated from nonlinear optical processes. Such a process is facilitated by coherent two-photon excitation of the strongly bound biexciton in atomically thin semiconductors. We show theoretically that interfacing an atomically thin semiconductor with an optical cavity allows to harness this two-photon resonance and use the biexcitonic parametric gain to generate squeezed light with input power an order of magnitude below current state-of-the-art devices with conventional third-order nonlinear materials that rely on far off-resonant nonlinearities. Furthermore, the squeezing bandwidth is found to be in the range of several meV. These results identify atomically thin semiconductors as a promising candidate for on-chip squeezed-light sources.
Cite
@article{arxiv.2203.04567,
title = {Efficient quadrature-squeezing from biexcitonic parametric gain in atomically thin semiconductors},
author = {Emil V. Denning and Andreas Knorr and Florian Katsch and Marten Richter},
journal= {arXiv preprint arXiv:2203.04567},
year = {2022}
}
Comments
Postprint version