Related papers: Squeezed Light via Exciton-Phonon Cavity QED

Squeezed Light via Exciton-Phonon Cavity QED

URL: http://arxiv.org/abs/2408.09323v1
Date: Sun, 18 Aug 2024 01:27:23 GMT
Title: Squeezed Light via Exciton-Phonon Cavity QED
Authors: Xuan Zuo, Zi-Xu Lu, Zhi-Yuan Fan, Jie Li,
Abstract summary: We introduce a new mechanism and system to produce squeezed light using an exciton-phonon cavity-QED system. We show that the strong exciton-phonon nonlinear interaction can induce a quadrature-squeezed cavity output field.
Score: 4.561414434532408
License: http://creativecommons.org/publicdomain/zero/1.0/
Abstract: Squeezed light is a particularly useful quantum resource, which finds broad applications in quantum information processing, quantum metrology and sensing, and biological measurements. It has been successfully generated in various physical systems. Here we introduce a new mechanism and system to produce squeezed light using an exciton-phonon cavity-QED system. Specifically, we adopt a semiconductor microcavity embedded with a quantum well, which supports both linear and nonlinear interactions among excitons, phonons, and cavity photons. We show that the strong exciton-phonon nonlinear interaction can induce a quadrature-squeezed cavity output field, and reveal an important role of the exciton-photon coupling in engineering the squeezing spectrum and improving the robustness of the squeezing against thermal noise. Our results indicate that room-temperature squeezing of light is possible for materials with high exciton binding energy.

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