Searching for dark matter with plasma haloscopes

Alexander J. Millar; Steven M. Anlage; Rustam Balafendiev; Pavel Belov; Karl Van Bibber; Jan Conrad; Marcel Demarteau; Alexander Droster; Katherine Dunne; Andrea Gallo Rosso; Jon E. Gudmundsson; Heather Jackson; Gagandeep Kaur; Tove Klaesson; Nolan Kowitt; Matthew Lawson; Alexander Leder; Akira Miyazaki; Sid Morampudi; Hiranya V. Peiris; Henrik S. Røising; Gaganpreet Singh; Dajie Sun; Jacob H. Thomas; Frank Wilczek; Stafford Withington; Mackenzie Wooten; Jens Dilling; Michael Febbraro; Stefan Knirck; Claire Marvinney

doi:10.1103/PhysRevD.107.055013

Searching for dark matter with plasma haloscopes

Alexander J. Millar, Steven M. Anlage, Rustam Balafendiev, Pavel Belov, Karl Van Bibber, Jan Conrad, Marcel Demarteau, Alexander Droster, Katherine Dunne, Andrea Gallo Rosso, Jon E. Gudmundsson, Heather Jackson, Gagandeep Kaur, Tove Klaesson, Nolan Kowitt, Matthew Lawson, Alexander Leder, Akira Miyazaki, Sid Morampudi, Hiranya V. PeirisHenrik S. Røising, Gaganpreet Singh, Dajie Sun, Jacob H. Thomas, Frank Wilczek, Stafford Withington, Mackenzie Wooten, Jens Dilling, Michael Febbraro, Stefan Knirck, Claire Marvinney

Physics

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

14 Scopus citations

Abstract

We summarize the recent progress of the Axion Longitudinal Plasma Haloscope (ALPHA) Consortium, a new experimental collaboration to build a plasma haloscope to search for axions and dark photons. The plasma haloscope is a novel method for the detection of the resonant conversion of light dark matter to photons. ALPHA will be sensitive to QCD axions over almost a decade of parameter space, potentially discovering dark matter and resolving the strong CP problem. Unlike traditional cavity haloscopes, which are generally limited in volume by the Compton wavelength of the dark matter, plasma haloscopes use a wire metamaterial to create a tuneable artificial plasma frequency, decoupling the wavelength of light from the Compton wavelength and allowing for much stronger signals. We develop the theoretical foundations of plasma haloscopes and discuss recent experimental progress. Finally, we outline a baseline design for ALPHA and show that a full-scale experiment could discover QCD axions over almost a decade of parameter space.

Original language	English (US)
Article number	055013
Journal	Physical Review D
Volume	107
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevD.107.055013
State	Published - Mar 1 2023

ASJC Scopus subject areas

Nuclear and High Energy Physics

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10.1103/PhysRevD.107.055013

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Millar, A. J., Anlage, S. M., Balafendiev, R., Belov, P., Van Bibber, K., Conrad, J., Demarteau, M., Droster, A., Dunne, K., Rosso, A. G., Gudmundsson, J. E., Jackson, H., Kaur, G., Klaesson, T., Kowitt, N., Lawson, M., Leder, A., Miyazaki, A., Morampudi, S., ... Marvinney, C. (2023). Searching for dark matter with plasma haloscopes. Physical Review D, 107(5), Article 055013. https://doi.org/10.1103/PhysRevD.107.055013

Millar, AJ, Anlage, SM, Balafendiev, R, Belov, P, Van Bibber, K, Conrad, J, Demarteau, M, Droster, A, Dunne, K, Rosso, AG, Gudmundsson, JE, Jackson, H, Kaur, G, Klaesson, T, Kowitt, N, Lawson, M, Leder, A, Miyazaki, A, Morampudi, S, Peiris, HV, Røising, HS, Singh, G, Sun, D, Thomas, JH, Wilczek, F, Withington, S, Wooten, M, Dilling, J, Febbraro, M, Knirck, S & Marvinney, C 2023, 'Searching for dark matter with plasma haloscopes', Physical Review D, vol. 107, no. 5, 055013. https://doi.org/10.1103/PhysRevD.107.055013

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title = "Searching for dark matter with plasma haloscopes",

abstract = "We summarize the recent progress of the Axion Longitudinal Plasma Haloscope (ALPHA) Consortium, a new experimental collaboration to build a plasma haloscope to search for axions and dark photons. The plasma haloscope is a novel method for the detection of the resonant conversion of light dark matter to photons. ALPHA will be sensitive to QCD axions over almost a decade of parameter space, potentially discovering dark matter and resolving the strong CP problem. Unlike traditional cavity haloscopes, which are generally limited in volume by the Compton wavelength of the dark matter, plasma haloscopes use a wire metamaterial to create a tuneable artificial plasma frequency, decoupling the wavelength of light from the Compton wavelength and allowing for much stronger signals. We develop the theoretical foundations of plasma haloscopes and discuss recent experimental progress. Finally, we outline a baseline design for ALPHA and show that a full-scale experiment could discover QCD axions over almost a decade of parameter space.",

author = "Millar, {Alexander J.} and Anlage, {Steven M.} and Rustam Balafendiev and Pavel Belov and {Van Bibber}, Karl and Jan Conrad and Marcel Demarteau and Alexander Droster and Katherine Dunne and Rosso, {Andrea Gallo} and Gudmundsson, {Jon E.} and Heather Jackson and Gagandeep Kaur and Tove Klaesson and Nolan Kowitt and Matthew Lawson and Alexander Leder and Akira Miyazaki and Sid Morampudi and Peiris, {Hiranya V.} and R{\o}ising, {Henrik S.} and Gaganpreet Singh and Dajie Sun and Thomas, {Jacob H.} and Frank Wilczek and Stafford Withington and Mackenzie Wooten and Jens Dilling and Michael Febbraro and Stefan Knirck and Claire Marvinney",

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AU - Belov, Pavel

AU - Van Bibber, Karl

AU - Conrad, Jan

AU - Demarteau, Marcel

AU - Droster, Alexander

AU - Dunne, Katherine

AU - Rosso, Andrea Gallo

AU - Gudmundsson, Jon E.

AU - Jackson, Heather

AU - Kaur, Gagandeep

AU - Klaesson, Tove

AU - Kowitt, Nolan

AU - Lawson, Matthew

AU - Leder, Alexander

AU - Miyazaki, Akira

AU - Morampudi, Sid

AU - Peiris, Hiranya V.

AU - Røising, Henrik S.

AU - Singh, Gaganpreet

AU - Sun, Dajie

AU - Thomas, Jacob H.

AU - Wilczek, Frank

AU - Withington, Stafford

AU - Wooten, Mackenzie

AU - Dilling, Jens

AU - Febbraro, Michael

AU - Knirck, Stefan

AU - Marvinney, Claire

N1 - Publisher Copyright: © 2023 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the "https://creativecommons.org/licenses/by/4.0/"Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI. Funded by SCOAP3.

PY - 2023/3/1

Y1 - 2023/3/1

N2 - We summarize the recent progress of the Axion Longitudinal Plasma Haloscope (ALPHA) Consortium, a new experimental collaboration to build a plasma haloscope to search for axions and dark photons. The plasma haloscope is a novel method for the detection of the resonant conversion of light dark matter to photons. ALPHA will be sensitive to QCD axions over almost a decade of parameter space, potentially discovering dark matter and resolving the strong CP problem. Unlike traditional cavity haloscopes, which are generally limited in volume by the Compton wavelength of the dark matter, plasma haloscopes use a wire metamaterial to create a tuneable artificial plasma frequency, decoupling the wavelength of light from the Compton wavelength and allowing for much stronger signals. We develop the theoretical foundations of plasma haloscopes and discuss recent experimental progress. Finally, we outline a baseline design for ALPHA and show that a full-scale experiment could discover QCD axions over almost a decade of parameter space.

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Searching for dark matter with plasma haloscopes

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