Constraints on dark photon dark matter using data from LIGO's and Virgo's third observing run

(LIGO Scientific Collaboration, Virgo Collaboration, and KAGRA Collaboration)

doi:10.1103/PhysRevD.105.063030

Constraints on dark photon dark matter using data from LIGO's and Virgo's third observing run

(LIGO Scientific Collaboration, Virgo Collaboration, and KAGRA Collaboration)

Applied Mathematics and Statistics

California Institute of Technology
Louisiana State University
University of Salerno
Monash University
National Science Foundation
University of Wisconsin-Milwaukee
Australian National University
Max Planck Institute for Gravitational Physics (Albert Einstein Institute)
Leibniz University Hannover
Inter-University Centre for Astronomy and Astrophysics India
University of Cambridge
Friedrich Schiller University Jena
University of Birmingham
Northwestern University
Instituto Nacional de Pesquisas Espaciais
Cardiff University
National Institute for Nuclear Physics
Tata Institute of Fundamental Research
National Astronomical Observatory of Japan (NAOJ)
University of Naples Federico II
Universite Claude Bernard Lyon 1
The University of Tokyo
University of Barcelona
Université Grenoble Alpes
Gran Sasso Science Institute
University of Strathclyde
University of Udine
Embry-Riddle Aeronautical University
Université Paris Cité
High Energy Accelerator Research Organization, Accelerator Laboratory
California State University Fullerton
Université Paris-Saclay
European Gravitational Observatory
SPIC Science Foundation
Hirosaki University

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

64 Scopus citations

Abstract

We present a search for dark photon dark matter that could couple to gravitational-wave interferometers using data from Advanced LIGO and Virgo's third observing run. To perform this analysis, we use two methods, one based on cross-correlation of the strain channels in the two nearly aligned LIGO detectors, and one that looks for excess power in the strain channels of the LIGO and Virgo detectors. The excess power method optimizes the Fourier transform coherence time as a function of frequency, to account for the expected signal width due to Doppler modulations. We do not find any evidence of dark photon dark matter with a mass between mA∼10-14-10-11 eV/c2, which corresponds to frequencies between 10-2000 Hz, and therefore provide upper limits on the square of the minimum coupling of dark photons to baryons, i.e., U(1)B dark matter. For the cross-correlation method, the best median constraint on the squared coupling is ∼1.31×10-47 at mA∼4.2×10-13 eV/c2; for the other analysis, the best constraint is ∼2.4×10-47 at mA∼5.7×10-13 eV/c2. These limits improve upon those obtained in direct dark matter detection experiments by a factor of ∼100 for mA∼[2-4]×10-13 eV/c2, and are, in absolute terms, the most stringent constraint so far in a large mass range mA∼2×10-13-8×10-12 eV/c2.

Original language	English
Article number	063030
Journal	Physical Review D
Volume	105
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevD.105.063030
State	Published - Mar 15 2022

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10.1103/PhysRevD.105.063030

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@article{0fb3ac4fed4e44899a2d53e0a452d7e5,

title = "Constraints on dark photon dark matter using data from LIGO's and Virgo's third observing run",

abstract = "We present a search for dark photon dark matter that could couple to gravitational-wave interferometers using data from Advanced LIGO and Virgo's third observing run. To perform this analysis, we use two methods, one based on cross-correlation of the strain channels in the two nearly aligned LIGO detectors, and one that looks for excess power in the strain channels of the LIGO and Virgo detectors. The excess power method optimizes the Fourier transform coherence time as a function of frequency, to account for the expected signal width due to Doppler modulations. We do not find any evidence of dark photon dark matter with a mass between mA∼10-14-10-11 eV/c2, which corresponds to frequencies between 10-2000 Hz, and therefore provide upper limits on the square of the minimum coupling of dark photons to baryons, i.e., U(1)B dark matter. For the cross-correlation method, the best median constraint on the squared coupling is ∼1.31×10-47 at mA∼4.2×10-13 eV/c2; for the other analysis, the best constraint is ∼2.4×10-47 at mA∼5.7×10-13 eV/c2. These limits improve upon those obtained in direct dark matter detection experiments by a factor of ∼100 for mA∼[2-4]×10-13 eV/c2, and are, in absolute terms, the most stringent constraint so far in a large mass range mA∼2×10-13-8×10-12 eV/c2.",

author = "\{(LIGO Scientific Collaboration, Virgo Collaboration, and KAGRA Collaboration)\} and R. Abbott and Abbott, \{T. D.\} and F. Acernese and K. Ackley and C. Adams and N. Adhikari and Adhikari, \{R. X.\} and Adya, \{V. B.\} and C. Affeldt and D. Agarwal and M. Agathos and K. Agatsuma and N. Aggarwal and Aguiar, \{O. D.\} and L. Aiello and A. Ain and P. Ajith and T. Akutsu and S. Albanesi and A. Allocca and Altin, \{P. A.\} and A. Amato and C. Anand and S. Anand and A. Ananyeva and Anderson, \{S. B.\} and Anderson, \{W. G.\} and M. Ando and T. Andrade and N. Andres and T. Andri{\'c} and Angelova, \{S. V.\} and S. Ansoldi and Antelis, \{J. M.\} and S. Antier and S. Appert and Koji Arai and Koya Arai and Y. Arai and S. Araki and A. Araya and Araya, \{M. C.\} and Areeda, \{J. S.\} and M. Ar{\`e}ne and N. Aritomi and N. Arnaud and Aronson, \{S. M.\} and Arun, \{K. G.\} and H. Asada and C. Markakis",

year = "2022",

month = mar,

day = "15",

doi = "10.1103/PhysRevD.105.063030",

language = "English",

volume = "105",

journal = "Physical Review D",

issn = "2470-0010",

number = "6",

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TY - JOUR

T1 - Constraints on dark photon dark matter using data from LIGO's and Virgo's third observing run

AU - (LIGO Scientific Collaboration, Virgo Collaboration, and KAGRA Collaboration)

AU - Abbott, R.

AU - Abbott, T. D.

AU - Acernese, F.

AU - Ackley, K.

AU - Adams, C.

AU - Adhikari, N.

AU - Adhikari, R. X.

AU - Adya, V. B.

AU - Affeldt, C.

AU - Agarwal, D.

AU - Agathos, M.

AU - Agatsuma, K.

AU - Aggarwal, N.

AU - Aguiar, O. D.

AU - Aiello, L.

AU - Ain, A.

AU - Ajith, P.

AU - Akutsu, T.

AU - Albanesi, S.

AU - Allocca, A.

AU - Altin, P. A.

AU - Amato, A.

AU - Anand, C.

AU - Anand, S.

AU - Ananyeva, A.

AU - Anderson, S. B.

AU - Anderson, W. G.

AU - Ando, M.

AU - Andrade, T.

AU - Andres, N.

AU - Andrić, T.

AU - Angelova, S. V.

AU - Ansoldi, S.

AU - Antelis, J. M.

AU - Antier, S.

AU - Appert, S.

AU - Arai, Koji

AU - Arai, Koya

AU - Arai, Y.

AU - Araki, S.

AU - Araya, A.

AU - Araya, M. C.

AU - Areeda, J. S.

AU - Arène, M.

AU - Aritomi, N.

AU - Arnaud, N.

AU - Aronson, S. M.

AU - Arun, K. G.

AU - Asada, H.

AU - Markakis, C.

PY - 2022/3/15

Y1 - 2022/3/15

N2 - We present a search for dark photon dark matter that could couple to gravitational-wave interferometers using data from Advanced LIGO and Virgo's third observing run. To perform this analysis, we use two methods, one based on cross-correlation of the strain channels in the two nearly aligned LIGO detectors, and one that looks for excess power in the strain channels of the LIGO and Virgo detectors. The excess power method optimizes the Fourier transform coherence time as a function of frequency, to account for the expected signal width due to Doppler modulations. We do not find any evidence of dark photon dark matter with a mass between mA∼10-14-10-11 eV/c2, which corresponds to frequencies between 10-2000 Hz, and therefore provide upper limits on the square of the minimum coupling of dark photons to baryons, i.e., U(1)B dark matter. For the cross-correlation method, the best median constraint on the squared coupling is ∼1.31×10-47 at mA∼4.2×10-13 eV/c2; for the other analysis, the best constraint is ∼2.4×10-47 at mA∼5.7×10-13 eV/c2. These limits improve upon those obtained in direct dark matter detection experiments by a factor of ∼100 for mA∼[2-4]×10-13 eV/c2, and are, in absolute terms, the most stringent constraint so far in a large mass range mA∼2×10-13-8×10-12 eV/c2.

AB - We present a search for dark photon dark matter that could couple to gravitational-wave interferometers using data from Advanced LIGO and Virgo's third observing run. To perform this analysis, we use two methods, one based on cross-correlation of the strain channels in the two nearly aligned LIGO detectors, and one that looks for excess power in the strain channels of the LIGO and Virgo detectors. The excess power method optimizes the Fourier transform coherence time as a function of frequency, to account for the expected signal width due to Doppler modulations. We do not find any evidence of dark photon dark matter with a mass between mA∼10-14-10-11 eV/c2, which corresponds to frequencies between 10-2000 Hz, and therefore provide upper limits on the square of the minimum coupling of dark photons to baryons, i.e., U(1)B dark matter. For the cross-correlation method, the best median constraint on the squared coupling is ∼1.31×10-47 at mA∼4.2×10-13 eV/c2; for the other analysis, the best constraint is ∼2.4×10-47 at mA∼5.7×10-13 eV/c2. These limits improve upon those obtained in direct dark matter detection experiments by a factor of ∼100 for mA∼[2-4]×10-13 eV/c2, and are, in absolute terms, the most stringent constraint so far in a large mass range mA∼2×10-13-8×10-12 eV/c2.

UR - https://www.scopus.com/pages/publications/85128736654

U2 - 10.1103/PhysRevD.105.063030

DO - 10.1103/PhysRevD.105.063030

M3 - Article

AN - SCOPUS:85128736654

SN - 2470-0010

VL - 105

JO - Physical Review D

JF - Physical Review D

IS - 6

M1 - 063030

ER -

Constraints on dark photon dark matter using data from LIGO's and Virgo's third observing run

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