English

Pump Free Microwave-Optical Quantum Transduction

Quantum Physics 2025-12-05 v1

Abstract

Distributed quantum computing involves superconducting computation nodes operating at microwave frequencies, which are connected by long-distance transmission lines that transmit photons at optical frequencies. Quantum transduction, which coherently converts between microwave and optical (M-O) photons, is a critical component of such an architecture. Current approaches are hindered by the unavoidable problem of device heating due to the optical pump. In this work, we propose a pump-free scheme based on color centers that generates time-bin encoded M-O Bell pairs. Our scheme first creates spin-photon entanglement and then converts the spin state into a time-bin-encoded microwave photon using a strongly coupled Purcell-enhanced resonator. In our protocol, the microwave retrieval is heralded by detecting the microwave signal with a three-level transmon. We have analyzed the resulting Bell state fidelity and generation probability of this protocol. Our simulation shows that by combining a state-of-the-art spin-optical interface with our proposed strongly-coupled spin-microwave design, the pump-free scheme can generate M-O Bell pairs at a heralding rate exceeding one kilohertz with near-unity fidelity, which establishes the scheme as a promising source for M-O Bell pairs.

Keywords

Cite

@article{arxiv.2512.05096,
  title  = {Pump Free Microwave-Optical Quantum Transduction},
  author = {Fangxin Li and Jaesung Heo and Zhaoyou Wang and Andrew P. Higginbotham and Alexander A. High and Liang Jiang},
  journal= {arXiv preprint arXiv:2512.05096},
  year   = {2025}
}
R2 v1 2026-07-01T08:10:03.715Z