Quantum-Enhanced Dark-Matter Sensing with Large Fock States in a High-Q Multimode SRF Cavity
Oral-In-person
Abstract
Wave-like dark matter candidates such as axions or dark photons in the microwave frequency range can be probed using resonant superconducting cavities. We demonstrate a quantum-enhanced sensing approach based on a multimode, high-Q superconducting RF (SRF) cavity, where a large Fock state is prepared in the storage mode via sideband transitions mediated by a transmon ancilla and a measurement-based feedforward protocol, achieving high-fidelity Fock states [1]. The prepared |n⟩ state induces stimulated emission from the dark-matter field, providing an (n + 1) enhancement in transition probability and proportional boost in signal rate [2]. A secondary cavity mode functions as an in-situ reference to calibrate noise. We present the control sequence, noise-referencing strategy, and projected sensitivity improvements for axion and dark-photon detection. This multimode architecture combines large Fock state preparation with noise calibration, offering a practical path to increased scan rate in cavity-based dark-matter searches.
[1] arXiv:2506.03286
[2] Phys. Rev. Lett. 132, 140801
[1] arXiv:2506.03286
[2] Phys. Rev. Lett. 132, 140801
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Presenters
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Taeyoon Kim
- Northwestern University