Abstract
The axion is a hypothetical low-mass boson predicted by the Peccei-Quinn mechanism solving the strong CP problem. It is naturally also a cold dark matter candidate if its mass is below ∼1 meV, thus simultaneously solving two major problems of nature. All existing experimental efforts to detect QCD axions focus on a range of axion masses below ∼25 μeV. The mass range above ∼40 μeV, predicted by modern models in which the Peccei-Quinn symmetry was restored after inflation, could not be explored so far. The MADMAX project is designed to be sensitive for axions with masses (40–400) μeV. The experimental design is based on the idea of enhanced axion-photon conversion in a system with several layers with alternating dielectric constants. The concept and the proposed design of the MADMAX experiment are discussed. Measurements taken with a prototype test setup are discussed. The prospects for reaching sensitivity enough to cover the parameter space predicted for QCD dark matter axions with mass in the range around 100 μeV is presented.
Highlights
The mass range above ∼ 40 μeV, predicted by modern models in which the Peccei-Quinn symmetry was restored after inflation, could not be explored so far
Most experiments looking for dark matter axions are sensitive in the axion mass range below ∼ 25 μeV [1]
This mass range is plausible in the scenario where Peccei-Quinn (PQ) symmetry was broken before inflation
Summary
Most experiments looking for dark matter axions are sensitive in the axion mass range below ∼ 25 μeV [1]. The prospects for reaching sensitivity enough to cover the parameter space predicted for QCD dark matter axions with mass in the range around 100 μeV is presented. 1. Introduction Most experiments looking for dark matter axions are sensitive in the axion mass range below ∼ 25 μeV [1].
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