A cavity entanglement and state swapping method to accelerate the search for axion dark matter

TL;DR

This paper proposes a novel cavity entanglement and state swapping method that significantly enhances the scan rate of axion dark matter detectors by amplifying signals internally, potentially increasing search efficiency up to 15 times.

Contribution

It introduces a new quantum technique combining two-mode squeezing and state swapping to amplify axion signals within the detector, surpassing previous noise limitations.

Findings

Scan rate can be increased up to 15-fold.

Method amplifies axion signals before measurement noise contamination.

Analytical and simulation results support effectiveness.

Abstract

In cavity-based axion dark matter detectors, quantum noise remains a primary barrier to achieving the scan rate necessary for a comprehensive search of axion parameter space. Here we introduce a method of scan rate enhancement in which an axion-sensitive cavity is coupled to an auxiliary resonant circuit through simultaneous two-mode squeezing (entangling) and state swapping interactions. We show analytically that when combined, these interactions can amplify an axion signal before it becomes polluted by vacuum noise introduced by measurement. This internal amplification yields a wider bandwidth of axion sensitivity, increasing the rate at which the detector can search through frequency space. With interaction rates predicted by circuit simulations of this system, we show that this technique can increase the scan rate up to 15-fold relative to the scan rate of a detector limited by vacuum noise.