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GW250114: Testing Hawking’s Area Law and the Kerr Nature of Black Holes

Adrian AbacMax Planck Institute for Gravitational Physics (Albert Einstein Institute)I. AbouelfettouhF. AcerneseINFNK. AckleyUniversity of WarwickChristian AdamcewiczMonash UniversityS. AdhicaryThe Pennsylvania State UniversityDadhi AdhikariLeibniz Universität HannoverN. AdhikariUniversity of Wisconsin-MilwaukeeR. X. AdhikariCalifornia Institute of TechnologyV.K AdkinsLouisiana State UniversitySamsuzzaman AfrozTata Institute of Fundamental ResearchA. AgapitoAix-Marseille UniversitéD. AgarwalUniversité catholique de LouvainM. AgathosQueen Mary University of LondonN. AggarwalUniversity of CaliforniaS. AggarwalUniversity of MinnesotaOdylio D. AguiarInstituto Nacional de Pesquisas EspaciaisI. -L. AhrendUniversité Paris CitéL. AielloINFNA. AinUniversiteit AntwerpenP. AjithTata Institute of Fundamental ResearchT. AkutsuNational Astronomical Observatory of JapanS. Al-KershiLeibniz Universität HannoverS. Al-ShammariCardiff UniversitySimone AlbanesiFriedrich-Schiller-Universität JenaWadah AliINFNC. AllénéUniversité Savoie Mont BlancA. AlloccaINFNP. A. AltinAustralian National UniversityS. Álvarez-LópezMassachusetts Institute of TechnologyW. AmarUniv. Savoie Mont BlancO. AmarasingheCardiff UniversityA. AmatoMaastricht UniversityF. AmicucciINFNClaude AmraAix Marseille UnivA. AnanyevaCalifornia Institute of TechnologyS. B. AndersonCalifornia Institute of TechnologyW. G. AndersonCalifornia Institute of TechnologyM. AndiaUniversité Paris-SaclayMakoto AndoUniversity of TokyoM. Andrés‐CarcasonaBarcelona Institute of Science and TechnologyT. AndrićGran Sasso Science Institute (GSSI)J. D. AnglinUniversity of FloridaStefano AnsoldiINFNJavier M. AntelisS. AntierUniversité Paris-SaclayM. AoumiThe University of TokyoE. Z. AppavuravtherINFNS. AppertCalifornia Institute of TechnologyS. K. AppleUniversity of WashingtonK. AraiCalifornia Institute of TechnologyA. ArayaUniversity of TokyoM. C. ArayaCalifornia Institute of TechnologyManuel Arca SeddaGran Sasso Science Institute (GSSI)J. S. AreedaCalifornia State University FullertonN. AritomiF. ArmatoINFNSharon ArmstrongUniversity of StrathclydeN. ArnaudUniversité Claude Bernard Lyon 1M. ArogetiGeorgia Institute of TechnologyScott AronsonLouisiana State UniversityG. AshtonUniversity of LondonY. AsoNational Astronomical Observatory of JapanL. AspreaINFN Sezione di TorinoM. AssiduoINFNS. Assis de Souza MeloEuropean Gravitational Observatory (EGO)S. M. AstonLIGO Livingston ObservatoryP. AstoneINFNF. AttadioINFNF. AubinUniversité de StrasbourgK. AultONealEmbry-Riddle Aeronautical UniversityGuerino AvalloneUniversità di SalernoE. A. AvilaS. BabakUniversité Paris CitéC. BadgerUniversity of LondonS. BaeKorea Institute of Science and Technology InformationS. BagnascoINFN Sezione di TorinoLuca BaiottiOsaka UniversityR. BajpaiHigh Energy Accelerator Research Organization (KEK)T. BakaNikhefAndrew BakerMonash UniversityKeith BakerUniversity of Western AustraliaTessa BakerUniversity of PortsmouthG. BaldiINFNN. BaldicchiINFNM. BallUniversity of OregonG. BallardinEuropean Gravitational Observatory (EGO)S. W. BallmerSyracuse UniversityS. BanagiriMonash UniversityB. BanerjeeGran Sasso Science Institute (GSSI)D. BankarInter-University Centre for Astronomy and AstrophysicsT. M. BaptisteLouisiana State UniversityPratyusava BaralUniversity of Wisconsin-MilwaukeeM. BarattiINFNJ. C. BarayogaCalifornia Institute of TechnologyB. C. BarishCalifornia Institute of TechnologyD. BarkerNilkanta BarmanInter-University Centre for Astronomy and AstrophysicsP. BarneoInstitut d’Estudis Espacials de CatalunyaF. BaroneINFN
2025lv
ABI

Abstract

The gravitational-wave signal GW250114 was observed by the two LIGO detectors with a network matched-filter signal-to-noise ratio of 80. The signal was emitted by the coalescence of two black holes with near-equal masses m_{1}=33.6_{-0.8}^{+1.2}M_{⊙} and m_{2}=32.2_{-1.3}^{+0.8}M_{⊙}, and small spins χ_{1,2}≤0.26 (90% credibility) and negligible eccentricity e≤0.03. Postmerger data excluding the peak region are consistent with the dominant quadrupolar (ℓ=|m|=2) mode of a Kerr black hole and its first overtone. We constrain the modes' frequencies to ±30% of the Kerr spectrum, providing a test of the remnant's Kerr nature. We also examine Hawking's area law, also known as the second law of black hole mechanics, which states that the total area of the black hole event horizons cannot decrease with time. A range of analyses that exclude up to five of the strongest merger cycles confirm that the remnant area is larger than the sum of the initial areas to high credibility.

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