Significantly enhanced detectability of dark photons with a steady-state excited microwave cavity

TL;DR

This paper proposes a novel method to significantly improve dark photon detection sensitivity using a steady-state excited microwave cavity, enabling first-order energy response signals and surpassing current techniques.

Contribution

It introduces a new detection scheme leveraging steady-state cavity excitation to coherently amplify dark photon signals, achieving at least ten times higher sensitivity.

Findings

First-order energy response signals can be coherently amplified.

Detection sensitivity is at least an order of magnitude higher.

Feasibility is supported by existing microwave and demodulation technologies.

Abstract

The resonant cavity system has been widely used to search for the electromagnetic response of dark photons, although its achievable detection sensitivity remains at a relatively low level. In this letter, we propose a feasible approach to significantly improve its achievable detection sensitivity by enhancing the detectability of the dark photon-photon dynamical effect, assisted with the steady-state excitation of the target mode in the cavity. Unlike in almost all the previous detection schemes, wherein where the cavity modes are kept in vacuum (and thus only the second-order energy signals can be detected), here the pre-excited steady-state field in the cavity can be used to achieve the coherent amplification of the dark photon response signal, thereby obtaining detectable first-order (rather than the conventional second-order) energy response signals of dark photons. Although the phase of the dark photon field and thus its electromagnetic response signal is stochastic, the amplitude of such a first-order energy response power signal can still be extracted by using mature IQ demodulation technology. As a consequence, we argue that, even considering the influence of the shot noise of the pre-excited steady-state field, the achievable detection sensitivity of this in-situ enhancement detectability, based on the steady-state excitation signal of the target mode, is still at least one order of magnitude higher than those of the current resonant cavity experiments with the same Q-quality factors. Based on existing microwave cavity and weak signal demodulation detection technologies, the feasibility of such a significantly enhanced detectability scheme is also discussed.