Microwave single-photon detection using a hybrid spin-optomechanical quantum interface
Abstract
Semiconductor single-photon detectors cannot be straightforwardly adapted for the microwave regime, primarily because microwave photons carry far less energy and thus require cryogenic temperatures and specialized architectures. Here, we propose a hybrid spin-optomechanical interface to detect single microwave photons where the microwave photons are coupled to a phononic resonator via piezoelectric actuation. This phononic cavity also acts as a photonic cavity with either a single embedded Silicon-Vacancy (SiV) center in diamond or an ensemble of these centers, bridging optical single-photon detection protocols into the microwave domain. We model the detection process as a communication channel whose capacity is quantified by the mutual information between the true photon occupancy (A) and the detector outcome (B). Depending on experimentally achievable parameters, simulations predict in the range to , corresponding to true-positive (detection) probabilities above 90\% and false-positive (dark count) probabilities below 10\% per detection interval. These results suggest a viable path to low-noise, high-efficiency single-photon detection at microwave frequencies.
Keywords
Cite
@article{arxiv.2401.10455,
title = {Microwave single-photon detection using a hybrid spin-optomechanical quantum interface},
author = {Pratyush Anand and Ethan G. Arnault and Matthew E. Trusheim and Kurt Jacobs and Dirk R. Englund},
journal= {arXiv preprint arXiv:2401.10455},
year = {2025}
}