Global fits of axion-like particles to XENON1T and astrophysical data

Peter Athron; Csaba Balázs; Ankit Beniwal; J. Eliel Camargo-Molina; Andrew Fowlie; Tomás E. Gonzalo; Sebastian Hoof; Felix Kahlhoefer; David J.E. Marsh; Markus Tobias Prim; Andre Scaffidi; Pat Scott; Wei Su; Martin White; Lei Wu; Yang Zhang

doi:10.1007/JHEP05(2021)159

Global fits of axion-like particles to XENON1T and astrophysical data

Peter Athron, Csaba Balázs, Ankit Beniwal, J. Eliel Camargo-Molina, Andrew Fowlie^*, Tomás E. Gonzalo, Sebastian Hoof, Felix Kahlhoefer, David J.E. Marsh, Markus Tobias Prim, Andre Scaffidi, Pat Scott, Wei Su, Martin White, Lei Wu, Yang Zhang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

28 Citations (Scopus)

Abstract

The excess of electron recoil events seen by the XENON1T experiment has been interpreted as a potential signal of axion-like particles (ALPs), either produced in the Sun, or constituting part of the dark matter halo of the Milky Way. It has also been explained as a consequence of trace amounts of tritium in the experiment. We consider the evidence for the solar and dark-matter ALP hypotheses from the combination of XENON1T data and multiple astrophysical probes, including horizontal branch stars, red giants, and white dwarfs. We briefly address the influence of ALP decays and supernova cooling. While the different datasets are in clear tension for the case of solar ALPs, all measurements can be simultaneously accommodated for the case of a sub-dominant fraction of dark-matter ALPs. Nevertheless, this solution requires the tuning of several a priori unknown parameters, such that for our choices of priors a Bayesian analysis shows no strong preference for the ALP interpretation of the XENON1T excess over the background hypothesis.

Original language	English
Article number	159
Journal	Journal of High Energy Physics
Volume	2021
Issue number	5
DOIs	https://doi.org/10.1007/JHEP05(2021)159
Publication status	Published - May 2021
Externally published	Yes

Keywords

Beyond Standard Model
Cosmology of Theories beyond the SM

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10.1007/JHEP05(2021)159

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Athron, P., Balázs, C., Beniwal, A., Camargo-Molina, J. E., Fowlie, A., Gonzalo, T. E., Hoof, S., Kahlhoefer, F., Marsh, D. J. E., Prim, M. T., Scaffidi, A., Scott, P., Su, W., White, M., Wu, L., & Zhang, Y. (2021). Global fits of axion-like particles to XENON1T and astrophysical data. Journal of High Energy Physics, 2021(5), Article 159. https://doi.org/10.1007/JHEP05(2021)159

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abstract = "The excess of electron recoil events seen by the XENON1T experiment has been interpreted as a potential signal of axion-like particles (ALPs), either produced in the Sun, or constituting part of the dark matter halo of the Milky Way. It has also been explained as a consequence of trace amounts of tritium in the experiment. We consider the evidence for the solar and dark-matter ALP hypotheses from the combination of XENON1T data and multiple astrophysical probes, including horizontal branch stars, red giants, and white dwarfs. We briefly address the influence of ALP decays and supernova cooling. While the different datasets are in clear tension for the case of solar ALPs, all measurements can be simultaneously accommodated for the case of a sub-dominant fraction of dark-matter ALPs. Nevertheless, this solution requires the tuning of several a priori unknown parameters, such that for our choices of priors a Bayesian analysis shows no strong preference for the ALP interpretation of the XENON1T excess over the background hypothesis.",

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author = "Peter Athron and Csaba Bal{\'a}zs and Ankit Beniwal and Camargo-Molina, {J. Eliel} and Andrew Fowlie and Gonzalo, {Tom{\'a}s E.} and Sebastian Hoof and Felix Kahlhoefer and Marsh, {David J.E.} and Prim, {Markus Tobias} and Andre Scaffidi and Pat Scott and Wei Su and Martin White and Lei Wu and Yang Zhang",

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doi = "10.1007/JHEP05(2021)159",

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AU - Athron, Peter

AU - Balázs, Csaba

AU - Beniwal, Ankit

AU - Camargo-Molina, J. Eliel

AU - Fowlie, Andrew

AU - Gonzalo, Tomás E.

AU - Hoof, Sebastian

AU - Kahlhoefer, Felix

AU - Marsh, David J.E.

AU - Prim, Markus Tobias

AU - Scaffidi, Andre

AU - Scott, Pat

AU - Su, Wei

AU - White, Martin

AU - Wu, Lei

AU - Zhang, Yang

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N2 - The excess of electron recoil events seen by the XENON1T experiment has been interpreted as a potential signal of axion-like particles (ALPs), either produced in the Sun, or constituting part of the dark matter halo of the Milky Way. It has also been explained as a consequence of trace amounts of tritium in the experiment. We consider the evidence for the solar and dark-matter ALP hypotheses from the combination of XENON1T data and multiple astrophysical probes, including horizontal branch stars, red giants, and white dwarfs. We briefly address the influence of ALP decays and supernova cooling. While the different datasets are in clear tension for the case of solar ALPs, all measurements can be simultaneously accommodated for the case of a sub-dominant fraction of dark-matter ALPs. Nevertheless, this solution requires the tuning of several a priori unknown parameters, such that for our choices of priors a Bayesian analysis shows no strong preference for the ALP interpretation of the XENON1T excess over the background hypothesis.

AB - The excess of electron recoil events seen by the XENON1T experiment has been interpreted as a potential signal of axion-like particles (ALPs), either produced in the Sun, or constituting part of the dark matter halo of the Milky Way. It has also been explained as a consequence of trace amounts of tritium in the experiment. We consider the evidence for the solar and dark-matter ALP hypotheses from the combination of XENON1T data and multiple astrophysical probes, including horizontal branch stars, red giants, and white dwarfs. We briefly address the influence of ALP decays and supernova cooling. While the different datasets are in clear tension for the case of solar ALPs, all measurements can be simultaneously accommodated for the case of a sub-dominant fraction of dark-matter ALPs. Nevertheless, this solution requires the tuning of several a priori unknown parameters, such that for our choices of priors a Bayesian analysis shows no strong preference for the ALP interpretation of the XENON1T excess over the background hypothesis.

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DO - 10.1007/JHEP05(2021)159

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JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

IS - 5

M1 - 159

ER -

Global fits of axion-like particles to XENON1T and astrophysical data

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Keywords

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