📝 SummarXiv

Abstract

The axion is a well-motivated and generic extension of the Standard Model. If produced in the early universe, axions may still be relativistic today, forming a Cosmic Axion Background (C$a$B) potentially detectable in direct detection experiments. A key challenge, however, is that the C$a$B is expected to have a broad energy spectrum, limiting the effectiveness of resonant cavity experiments designed for narrowband searches. We propose a new strategy using multi-cavity arrays to distinguish signal from background noise by exploiting spatial correlations in the axion-induced electric fields. We compute the two-point correlation function for electric fields in spatially separated cavities sourced by an isotropic C$a$B. Analyzing various cavity geometries, we find that stacked, wide-base cavity arrays offer optimal sensitivity to the axion signal. We apply our formalism to prospective upgrades of the ADMX experiment, including configurations with four and eighteen coupled cavities.