Dielectric Haloscopes to Search for Axion Dark Matter: Theoretical Foundations
arXiv:1612.07057 · doi:10.1088/1475-7516/2017/01/061
Abstract
We study the underlying theory of dielectric haloscopes, a new way to detect dark matter axions. When an interface between different dielectric media is inside a magnetic field, the oscillating axion field acts as a source of electromagnetic waves, which emerge in both directions perpendicular to the surface. The emission rate can be boosted by multiple layers judiciously placed to achieve constructive interference and by a large transverse area. Starting from the axion-modified Maxwell equations, we calculate the efficiency of this new dielectric haloscope approach. This technique could potentially search the unexplored high-frequency range of 10--100 GHz (axion mass 40--400 $μ$eV), where traditional cavity resonators have difficulties reaching the required volume.
71 pages, 34 figures; v2: minor changes, typo in (4.13) corrected, matches published version