Analytical study of birefringent cavities for axion-like dark matter search

Light polarization plays a crucial role in optical-cavity experiments; however, mirror birefringence presents a significant challenge that must be addressed carefully. In this study, a rigorous, nonperturbative framework is developed to quantify birefringence effects by incorporating variations in reflectance and polarization misalignment. We analyze the impact of this framework on the sensitivity of axion-like particle (ALP) dark-matter searches. The results show that both birefringence and misalignment contribute to sensitivity degradation in the low-mass regime; however, the adverse effects of misalignment can be mitigated by selecting a postselection angle greater than the misalignment angle. Furthermore, birefringence produces an additional resonance peak in the high-mass region, which remains largely unaffected by misalignment and postselection variations. This rigorous framework underscores the importance of considering birefringence in high-precision optical-cavity experiments for ALP detection.

💡 Research Summary

The authors present a comprehensive, non‑perturbative analysis of how mirror birefringence and polarization mis‑alignment affect optical‑cavity searches for axion‑like particles (ALPs). In contrast to earlier works that treated birefringence as a small perturbation, the paper models each mirror as an isotropic reflector coated with a complex wave‑plate characterized by a complex retardation α = Re