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Improved analysis framework for axion dark matter searches

Daniel Palken, Benjamin Brubaker, M. Malnou, S. Al Kenany, K. M. Backes, S. B. Cahn, Yulia V. Gurevich, S. K. Lamoreaux, Samantha M. Lewis, R. H. Maruyama, N. M. Rapidis, Jaben Root, Maria Simanovskaia, T. M. Shokair, Sukhman Singh, D. H. Speller, I. Urdinaran, K. van Bibber, L. Zhong, K. W. Lehnert

2020Physical review. D/Physical review. D.26 citationsDOIOpen Access PDF

Abstract

In experiments searching for axionic dark matter, the use of the standard threshold-based data analysis discards valuable information. We present a Bayesian analysis framework that builds on an existing processing protocol [B. M. Brubaker, L. Zhong, S. K. Lamoreaux, K. W. Lehnert, and K. A. van Bibber, Phys. Rev. D 96, 123008 (2017)] to extract more information from the data of coherent axion detectors such as operating haloscopes. The analysis avoids logical subtleties that accompany the standard analysis framework and enables greater experimental flexibility on future data runs. Performing this analysis on the existing data from the HAYSTAC experiment, we find improved constraints on the axion-photon coupling ${g}_{\ensuremath{\gamma}}$ while also identifying the most promising regions of parameter space within the $23.15--24.0\text{ }\text{ }\ensuremath{\mu}\mathrm{eV}$ mass range. A comparison with the standard threshold analysis suggests a 36% improvement in scan rate from our analysis, demonstrating the utility of this framework for future axion haloscope analyses.

Topics & Concepts

AxionPhysicsDark matterParticle physicsRange (aeronautics)DetectorParameter spaceCoupling (piping)Flexibility (engineering)StatisticsMathematicsOpticsEngineeringComposite materialMechanical engineeringMaterials scienceDark Matter and Cosmic PhenomenaParticle physics theoretical and experimental studiesParticle Detector Development and Performance