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Microwave cavity searches for low-frequency axion dark matter

Robert Lasenby

2020Physical review. D/Physical review. D.47 citationsDOIOpen Access PDF

Abstract

For low-mass (frequency $\ensuremath{\ll}\mathrm{GHz}$) axions, dark matter detection experiments searching for an axion-photon-photon coupling generally have suppressed sensitivity, if they use a static background magnetic field. This geometric suppression can be alleviated by using a high-frequency oscillating background field. Here, we present a high-level sketch of such an experiment, using superconducting cavities at $\ensuremath{\sim}\mathrm{GHz}$ frequencies. We discuss the physical limits on signal power arising from cavity properties, and point out cavity geometries that could circumvent some of these limitations. We also consider how backgrounds, including vibrational noise and drive signal leakage, might impact sensitivity. While practical microwave field strengths are significantly below attainable static magnetic fields, the lack of geometric suppression, and higher quality factors, may allow superconducting cavity experiments to be competitive in some regimes.

Topics & Concepts

AxionPhysicsDark matterSensitivity (control systems)MicrowaveSuperconductivityMagnetic fieldPhotonMicrowave cavityLow frequencyField (mathematics)Particle physicsCondensed matter physicsOpticsQuantum mechanicsElectronic engineeringPure mathematicsMathematicsEngineeringAstronomyDark Matter and Cosmic PhenomenaAtomic and Subatomic Physics ResearchCold Atom Physics and Bose-Einstein Condensates
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