Improving the sensitivity of planar Fabry-P\'erot cavities via adaptive optics and mode filtering

Fabry-P\'erot (FP) cavities are fundamental and ubiquitous optical elements frequently used in various sensing applications. Here, we introduce a general theoretical framework to study arbitrary light-cavity mode interactions for planar FPs and show how optical aberrations, intrinsic to the interrogating beam or due to imperfect cavities, reduce optical sensitivity by exciting higher-order spatial modes in the cavity. We find that particular Zernike aberrations play a dominant role in sensitivity degradation, and that the general loss of sensitivity can be significantly recovered by appropriate wavefront correction or mode filtering. We then demonstrate our theoretical findings also experimentally and show that in practice the sensitivity of realistic planar FP sensors can be improved up to three-fold by a synergistic combination of adaptive optics and passive mode filtering.