Black Hole Spectroscopy and Tests of General Relativity with GW250114

The LIGO Scientific Collaboration, the Virgo Collaboration, and the KAGRA Collaboration

doi:10.1103/6c61-fm1n

Black Hole Spectroscopy and Tests of General Relativity with GW250114

The LIGO Scientific Collaboration, the Virgo Collaboration, and the KAGRA Collaboration

Department of Physics - at Bar-Ilan University

Max Planck Institute for Gravitational Physics (Albert Einstein Institute)
National Science Foundation
University of Salerno
National Institute for Nuclear Physics
University of Warwick
Monash University
Pennsylvania State University
Leibniz University Hannover
University of Wisconsin-Milwaukee
California Institute of Technology
Louisiana State University
Tata Institute of Fundamental Research
CPT-Luminy
Université catholique de Louvain
Queen Mary University of London
University of California at Davis
University of Minnesota Twin Cities
Instituto Nacional de Pesquisas Espaciais
Université Paris Cité
University of Rome Tor Vergata
University of Antwerp
National Institutes of Natural Sciences - National Astronomical Observatory of Japan
Friedrich Schiller University Jena
University of Genoa
Université Savoie Mont Blanc
University of Naples Federico II
Cardiff University
Australian National University
Massachusetts Institute of Technology
Maastricht University
National Institute for Subatomic Physics
University of Rome La Sapienza
Institut Fresnel
Université Paris-Saclay
The University of Tokyo
Institute for High Energy Physics
Gran Sasso Science Institute
University of Florida
University of Udine
Instituto Tecnologico de Estudios Superiores de Monterrey
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University of Washington
California State University Fullerton
University of Strathclyde
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Georgia Institute of Technology
SPIC Science Foundation
Royal Holloway University of London
The Graduate University for Advanced Studies
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European Gravitational Observatory
Institut Pluridisciplinaire Hubert Curien
Embry-Riddle Aeronautical University
King's College London
Korea Institute of Science and Technology Information
The University of Osaka
High Energy Accelerator Research Organization, Accelerator Laboratory
Utrecht University
University of Western Australia
University of Portsmouth
University of Trento
University of Perugia
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University of Barcelona
Institute of Space Studies of Catalonia
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Wigner Research Centre for Physics
Concordia University Wisconsin
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University of Padua
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Ghent University
Polish Academy of Sciences
Northwestern University
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Raja Ramanna Centre for Advanced Technology
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Centre de Physique des Particules de Marseille
National Research Council of Italy
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University of the West of Scotland
Barry University
University of Lisbon
Eötvös Loránd University
Osaka Metropolitan University
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Universidad Autónoma de Madrid
Laboratoire d'Acoustique de l'Université du Mans
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University of California at Riverside
Roma Tre University
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University of Nottingham
Ariel University
University of Mississippi
Institute of Science Tokyo
Academia Sinica - Institute of Physics
Chinese University of Hong Kong
American University Washington DC
University of Milan
Fukuoka University
University of Cambridge
Lancaster University
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Directorate of Construction
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Chung-Ang University
Université Joseph Ki-Zerbo
Ewha Womans University
National Institute for Mathematical Sciences
Korea Astronomy and Space Science Institute
Chungnam National University
High Energy Accelerator Research Organization, Institute of Particle and Nuclear Physics
Nagoya University
Aristotle University of Thessaloniki
Bard College
Technical University of Braunschweig
Institute of Mathematics of the Polish Academy of Sciences
Jagiellonian University in Kraków
Polytechnique Montreal
Indian Institute of Science Education and Research, Kolkata
Seoul National University
Inje University
CNRS
National Cheng Kung University
St. Thomas University, Miami
Scuola Normale Superiore di Pisa
ICREA
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Tokyo City University
Tsinghua University
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Hiroshima University
University of Amsterdam
University College London
Observatoire de Paris
University of Maryland, Baltimore County
CSIR - Central Glass Ceramic Research Institute
Yonsei University
Hobart and William Smith Colleges
Astronomical Observatory of Padua
Kennesaw State University
IN2P3—IMT Atlantique—Nantes Université
Universidad de Antioquia
Technical University of Madrid
National Institute of Technology
Trinity College Hartford
University of Ferrara
Toho University
Indian Institute of Technology Gandhinagar
Peking University
Cité Descartes
Osaka Institute of Technology
NASA Goddard Space Flight Center
Kochi University
associé au CNRS et à l’Université P&M. Curie
Kyoto University
University of Catania
National Institute of Technology
National Defense Academy of Japan
Eindhoven University of Technology
Beijing Normal University
Wuhan University

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9 Scopus citations

Abstract

The binary black hole signal GW250114, the loudest gravitational wave detected to date, offers a unique opportunity to test Einstein’s general relativity (GR) in the high-velocity, strong-gravity regime and probe whether the remnant conforms to the Kerr metric. Upon perturbation, black holes emit a spectrum of damped sinusoids with specific, complex frequencies. Our analysis of the postmerger signal shows that at least two quasinormal modes are required to explain the data, with the most damped remaining statistically significant for about one cycle. We probe the remnant’s Kerr nature by constraining the spectroscopic pattern of the dominant quadrupolar ((Formula presented)) mode and its first overtone to match the Kerr prediction to tens of percent at multiple postpeak times. The measured mode amplitudes and phases agree with a numerical-relativity simulation having parameters close to GW250114. By fitting a parametrized waveform that incorporates the full inspiral-merger-ringdown sequence, we constrain the fundamental (Formula presented) mode to tens of percent and bound the quadrupolar frequency to within a few percent of the GR prediction. We perform a suite of tests—spanning inspiral, merger, and ringdown—finding constraints that are comparable to, and in some cases 2-3 times more stringent than those obtained by combining dozens of events in the fourth Gravitational-Wave Transient Catalog. These results constitute the most stringent single-event verification of GR and the Kerr nature of black holes to date, and outline the power of black-hole spectroscopy for future gravitational-wave observations.

Original language	English
Article number	041403
Journal	Physical Review Letters
Volume	136
Issue number	4
DOIs	https://doi.org/10.1103/6c61-fm1n
State	Published - 30 Jan 2026

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Publisher Copyright:
© 2026 Published by the American Physical Society.

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10.1103/6c61-fm1n

Cite this

@article{b69c42fa2e734394901b86f1db54726e,

title = "Black Hole Spectroscopy and Tests of General Relativity with GW250114",

abstract = "The binary black hole signal GW250114, the loudest gravitational wave detected to date, offers a unique opportunity to test Einstein{\textquoteright}s general relativity (GR) in the high-velocity, strong-gravity regime and probe whether the remnant conforms to the Kerr metric. Upon perturbation, black holes emit a spectrum of damped sinusoids with specific, complex frequencies. Our analysis of the postmerger signal shows that at least two quasinormal modes are required to explain the data, with the most damped remaining statistically significant for about one cycle. We probe the remnant{\textquoteright}s Kerr nature by constraining the spectroscopic pattern of the dominant quadrupolar ((Formula presented)) mode and its first overtone to match the Kerr prediction to tens of percent at multiple postpeak times. The measured mode amplitudes and phases agree with a numerical-relativity simulation having parameters close to GW250114. By fitting a parametrized waveform that incorporates the full inspiral-merger-ringdown sequence, we constrain the fundamental (Formula presented) mode to tens of percent and bound the quadrupolar frequency to within a few percent of the GR prediction. We perform a suite of tests—spanning inspiral, merger, and ringdown—finding constraints that are comparable to, and in some cases 2-3 times more stringent than those obtained by combining dozens of events in the fourth Gravitational-Wave Transient Catalog. These results constitute the most stringent single-event verification of GR and the Kerr nature of black holes to date, and outline the power of black-hole spectroscopy for future gravitational-wave observations.",

author = "\{The LIGO Scientific Collaboration, the Virgo Collaboration, and the KAGRA Collaboration\} and Abac, \{A. G.\} and I. Abouelfettouh and F. Acernese and K. Ackley and C. Adamcewicz and S. Adhicary and D. Adhikari and N. Adhikari and Adhikari, \{R. X.\} and Adkins, \{V. K.\} and S. Afroz and A. Agapito and D. Agarwal and M. Agathos and N. Aggarwal and S. Aggarwal and Aguiar, \{O. D.\} and Ahrend, \{I. L.\} and L. Aiello and A. Ain and P. Ajith and T. Akutsu and S. Albanesi and W. Ali and S. Al-Kershi and C. All{\'e}n{\'e} and A. Allocca and S. Al-Shammari and Altin, \{P. A.\} and S. Alvarez-Lopez and W. Amar and O. Amarasinghe and A. Amato and F. Amicucci and C. Amra and A. Ananyeva and Anderson, \{S. B.\} and Anderson, \{W. G.\} and M. Andia and M. Ando and M. Andr{\'e}s-Carcasona and T. Andri{\'c} and J. Anglin and S. Ansoldi and Antelis, \{J. M.\} and S. Antier and M. Aoumi and Appavuravther, \{E. Z.\} and S. Appert and O. Birnholtz",

note = "Publisher Copyright: {\textcopyright} 2026 Published by the American Physical Society.",

year = "2026",

month = jan,

day = "30",

doi = "10.1103/6c61-fm1n",

language = "אנגלית",

volume = "136",

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T1 - Black Hole Spectroscopy and Tests of General Relativity with GW250114

AU - The LIGO Scientific Collaboration, the Virgo Collaboration, and the KAGRA Collaboration

AU - Abac, A. G.

AU - Abouelfettouh, I.

AU - Acernese, F.

AU - Ackley, K.

AU - Adamcewicz, C.

AU - Adhicary, S.

AU - Adhikari, D.

AU - Adhikari, N.

AU - Adhikari, R. X.

AU - Adkins, V. K.

AU - Afroz, S.

AU - Agapito, A.

AU - Agarwal, D.

AU - Agathos, M.

AU - Aggarwal, N.

AU - Aggarwal, S.

AU - Aguiar, O. D.

AU - Ahrend, I. L.

AU - Aiello, L.

AU - Ain, A.

AU - Ajith, P.

AU - Akutsu, T.

AU - Albanesi, S.

AU - Ali, W.

AU - Al-Kershi, S.

AU - Alléné, C.

AU - Allocca, A.

AU - Al-Shammari, S.

AU - Altin, P. A.

AU - Alvarez-Lopez, S.

AU - Amar, W.

AU - Amarasinghe, O.

AU - Amato, A.

AU - Amicucci, F.

AU - Amra, C.

AU - Ananyeva, A.

AU - Anderson, S. B.

AU - Anderson, W. G.

AU - Andia, M.

AU - Ando, M.

AU - Andrés-Carcasona, M.

AU - Andrić, T.

AU - Anglin, J.

AU - Ansoldi, S.

AU - Antelis, J. M.

AU - Antier, S.

AU - Aoumi, M.

AU - Appavuravther, E. Z.

AU - Appert, S.

AU - Birnholtz, O.

PY - 2026/1/30

Y1 - 2026/1/30

N2 - The binary black hole signal GW250114, the loudest gravitational wave detected to date, offers a unique opportunity to test Einstein’s general relativity (GR) in the high-velocity, strong-gravity regime and probe whether the remnant conforms to the Kerr metric. Upon perturbation, black holes emit a spectrum of damped sinusoids with specific, complex frequencies. Our analysis of the postmerger signal shows that at least two quasinormal modes are required to explain the data, with the most damped remaining statistically significant for about one cycle. We probe the remnant’s Kerr nature by constraining the spectroscopic pattern of the dominant quadrupolar ((Formula presented)) mode and its first overtone to match the Kerr prediction to tens of percent at multiple postpeak times. The measured mode amplitudes and phases agree with a numerical-relativity simulation having parameters close to GW250114. By fitting a parametrized waveform that incorporates the full inspiral-merger-ringdown sequence, we constrain the fundamental (Formula presented) mode to tens of percent and bound the quadrupolar frequency to within a few percent of the GR prediction. We perform a suite of tests—spanning inspiral, merger, and ringdown—finding constraints that are comparable to, and in some cases 2-3 times more stringent than those obtained by combining dozens of events in the fourth Gravitational-Wave Transient Catalog. These results constitute the most stringent single-event verification of GR and the Kerr nature of black holes to date, and outline the power of black-hole spectroscopy for future gravitational-wave observations.

AB - The binary black hole signal GW250114, the loudest gravitational wave detected to date, offers a unique opportunity to test Einstein’s general relativity (GR) in the high-velocity, strong-gravity regime and probe whether the remnant conforms to the Kerr metric. Upon perturbation, black holes emit a spectrum of damped sinusoids with specific, complex frequencies. Our analysis of the postmerger signal shows that at least two quasinormal modes are required to explain the data, with the most damped remaining statistically significant for about one cycle. We probe the remnant’s Kerr nature by constraining the spectroscopic pattern of the dominant quadrupolar ((Formula presented)) mode and its first overtone to match the Kerr prediction to tens of percent at multiple postpeak times. The measured mode amplitudes and phases agree with a numerical-relativity simulation having parameters close to GW250114. By fitting a parametrized waveform that incorporates the full inspiral-merger-ringdown sequence, we constrain the fundamental (Formula presented) mode to tens of percent and bound the quadrupolar frequency to within a few percent of the GR prediction. We perform a suite of tests—spanning inspiral, merger, and ringdown—finding constraints that are comparable to, and in some cases 2-3 times more stringent than those obtained by combining dozens of events in the fourth Gravitational-Wave Transient Catalog. These results constitute the most stringent single-event verification of GR and the Kerr nature of black holes to date, and outline the power of black-hole spectroscopy for future gravitational-wave observations.

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U2 - 10.1103/6c61-fm1n

DO - 10.1103/6c61-fm1n

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JO - Physical Review Letters

JF - Physical Review Letters

IS - 4

M1 - 041403

ER -

Black Hole Spectroscopy and Tests of General Relativity with GW250114

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