Hooman Davoudiasl, Yannis K. Semertzidis

We propose a new axion dark matter detection strategy that employs optical readout of laser beam ellipticity modulations caused by axion-induced electric fields in a microwave cavity, using electro-optic (EO) crystals, enhanced by externally injected radio-frequency (RF) power. Building upon the variance-based probing method, PRD 107, 103005, (2023), we extend this concept to the optical domain: a weak probe laser interacts with an EO crystal placed inside a resonant microwave cavity at cryogenic temperatures, and the axion-induced electric field is revealed through induced ellipticity. The injected RF signal coherently interferes with that of the axion field, amplifying the optical response and significantly improving sensitivity. While our EO-based method employs a Fabry-Perot resonator, we do not require Michelson interferometers. Our method hence enables compact, high-frequency axion searches, across the 0.5-50\,GHz range. Operating at cryogenic temperatures not only suppresses thermal backgrounds but, critically, allows the probing method to mitigate the laser quantum noise. This approach offers a scalable path forward for axion detection over the $\sim (\text{few}-200$)~$\mu$eV mass range -- covering the preferred parameter space for the post-inflationary Peccei-Quinn axion dark matter -- using compact, tunable systems.