English

Microwave single-photon detection using a hybrid spin-optomechanical quantum interface

Quantum Physics 2025-01-22 v2

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 I(A;B)I(A;B) between the true photon occupancy (A) and the detector outcome (B). Depending on experimentally achievable parameters, simulations predict I(A;B)I(A;B) in the range 0.57ln(2)0.57\,\ln(2) to 0.67ln(2)0.67\,\ln(2), 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}
}
R2 v1 2026-06-28T14:21:07.436Z