Quantum-enhanced dark matter detection with in-cavity control: mitigating the Rayleigh curse

TL;DR

This paper introduces an in-cavity quantum protocol using squeezed states to improve dark matter detection sensitivity, effectively mitigating the Rayleigh curse and enhancing quantum advantage in microwave cavity experiments.

Contribution

It proposes a novel in-situ quantum protocol with specific state preparation and measurement strategies to overcome the Rayleigh limit in dark matter detection.

Findings

TMSS offers higher sensitivity at low temperatures.

Optimal axion accumulation time decreases with increased squeezing gain.

The protocol is compatible with current axion detection technologies.

Abstract

The nature of dark matter is a fundamental puzzle in modern physics. A major approach of searching for dark matter relies on detecting feeble noise in microwave cavities. However, the quantum advantages of common quantum resources such as squeezing are intrinsically limited by the Rayleigh curse -- a constant loss places a sensitivity upper bound on these quantum resources. In this paper, we propose an in-situ protocol to mitigate such Rayleigh limit. The protocol consists of three steps: in-cavity quantum state preparation, axion accumulation with tunable time duration, and measurement. For the quantum source, we focus on the single-mode squeezed state (SMSS), and the entanglement-assisted case using signal-ancilla pairs in two-mode squeezed state (TMSS), where the ancilla does not interact with the axion. From quantum Fisher information rate evaluation, we derive the requirement of cavity quality factor, thermal noise level and squeezing gain for quantum advantage. When the squeezing gain becomes larger, the optimal axion accumulation time decreases to reduce loss and mitigate the Rayleigh curse -- the quantum advantage keeps increasing with the squeezing gain. Overall, we find that TMSS is more sensitive in the low temperature limit. In the case of SMSS, as large gain is required for advantage over vacuum, homodyne is sufficient to achieve optimality. For TMSS, anti-squeezing and photon counting is necessary to be optimal. Thanks to the recent advance in magnetic-field-resilient in-cavity squeezing and rapidly coupling out for photon counting, the proposed protocol is compatible with axion detection scenario.