A single incident photon triggers a giant photon-number jump in a bistable nonlinear optical cavity through quantum dynamics, suggesting an all-optical single-photon avalanche detector.
High-Efficiency Tunable Microwave Photon Detector Based on a Semiconductor Double Quantum Dot Coupled to a Superconducting High-Impedance Cavity
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
High-efficiency single-photon detection in the microwave domain is a key enabling technology for quantum sensing, communication, and information processing. However, the extremely low energy of microwave photons (~{\mu}eV) presents a fundamental challenge, preventing direct photon-to-charge conversion as achieved in optical systems using semiconductors. Semiconductor quantum dot (QD) charge qubits offer a compelling solution due to their highly tunable energy levels in the microwave regime, enabling coherent coupling with single photons. In this work, we demonstrate microwave photon detection with an efficiency approaching 70% in the single-photon regime. We use a hybrid system comprising a double quantum dot (DQD) charge qubit electrostatically defined in a GaAs/AlGaAs heterostructure, coupled to a high-impedance Josephson junction (JJ) array cavity. We systematically optimize the hybrid device architecture to maximize the conversion efficiency, leveraging the strong charge-photon coupling and the tunable DQD tunnel coupling rates. Incoming cavity photons coherently excite the DQD qubit, which in turn generates a measurable electrical current, realizing deterministic photon-to-charge conversion. Moreover, by exploiting the independent tunability of both the DQD transition energy and the cavity resonance frequency, we characterize the system efficiency over a range of 3-5.2 GHz. Our results establish semiconductor-based cavity-QED architectures as a scalable and versatile platform for efficient microwave photon detection, opening new avenues for quantum microwave optics and hybrid quantum information technologies.
fields
quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
Analytical expressions for detection range of quantum direct-detection and entangled-noise radars are derived, with entangled versions treated as enhanced direct-detection systems and a range enhancement factor defined versus classical noise radars.
citing papers explorer
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Photon avalanche triggered by a single photon in a bistable nonlinear optical cavity
A single incident photon triggers a giant photon-number jump in a bistable nonlinear optical cavity through quantum dynamics, suggesting an all-optical single-photon avalanche detector.
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Analytical performance evaluation of quantum radar architectures: From single-photon to entangled-noise radars
Analytical expressions for detection range of quantum direct-detection and entangled-noise radars are derived, with entangled versions treated as enhanced direct-detection systems and a range enhancement factor defined versus classical noise radars.