<p>The detection of a stochastic gravitational wave background by pulsar-timing arrays indicates the presence of a population of supermassive black hole binaries. Although the observed spectrum generally matches predictions for orbital evolution driven by gravitational-wave emission in circular orbits, there is a preference for a spectral turnover at the lowest observed frequencies, which may point to substantial hardening during a transition from early environmental influences to later stages dominated by emission. In the vicinity of these binaries, the ejection of stars or dark matter particles through gravitational three-body slingshots efficiently extracts orbital energy, leading to a low-frequency turnover in the spectrum. Here we model how the gravitational-wave spectrum depends on the initial inner galactic profile before scouring by binary ejections while accounting for a range of initial binary eccentricities. By analysing the NANOGrav 15-year data, we find that a parsec-scale galactic-centre density of around 10<sup>6</sup> <i>M</i><sub>⊙</sub> pc<sup>−</sup><sup>3</sup> is favoured across most of the parameter space, thus shedding light on the environmental effects that shape black hole evolution and the combined matter density near galaxy centres.</p>

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Inference on inner galaxy structure via gravitational waves from supermassive binaries

  • Yifan Chen,
  • Matthias Daniel,
  • Daniel J. D’Orazio,
  • Xuanye Fan,
  • Andrea Mitridate,
  • Laura Sagunski,
  • Xiao Xue,
  • Gabriella Agazie,
  • Akash Anumarlapudi,
  • Anne M. Archibald,
  • Zaven Arzoumanian,
  • Jeremy G. Baier,
  • Paul T. Baker,
  • Bence Bécsy,
  • Laura Blecha,
  • Adam Brazier,
  • Paul R. Brook,
  • Sarah Burke-Spolaor,
  • Rand Burnette,
  • J. Andrew Casey-Clyde,
  • Maria Charisi,
  • Shami Chatterjee,
  • Tyler Cohen,
  • James M. Cordes,
  • Neil J. Cornish,
  • Fronefield Crawford,
  • H. Thankful Cromartie,
  • Kathryn Crowter,
  • Megan E. DeCesar,
  • Paul B. Demorest,
  • Heling Deng,
  • Lankeswar Dey,
  • Timothy Dolch,
  • Elizabeth C. Ferrara,
  • William Fiore,
  • Emmanuel Fonseca,
  • Gabriel E. Freedman,
  • Emiko C. Gardiner,
  • Nate Garver-Daniels,
  • Peter A. Gentile,
  • Kyle A. Gersbach,
  • Joseph Glaser,
  • Deborah C. Good,
  • Kayhan Gültekin,
  • Jeffrey S. Hazboun,
  • Ross J. Jennings,
  • Aaron D. Johnson,
  • Megan L. Jones,
  • David L. Kaplan,
  • Luke Zoltan Kelley,
  • Matthew Kerr,
  • Joey S. Key,
  • Nima Laal,
  • Michael T. Lam,
  • William G. Lamb,
  • Bjorn Larsen,
  • T. Joseph W. Lazio,
  • Natalia Lewandowska,
  • Tingting Liu,
  • Duncan R. Lorimer,
  • Jing Luo,
  • Ryan S. Lynch,
  • Chung-Pei Ma,
  • Dustin R. Madison,
  • Alexander McEwen,
  • James W. McKee,
  • Maura A. McLaughlin,
  • Natasha McMann,
  • Bradley W. Meyers,
  • Patrick M. Meyers,
  • Chiara M. F. Mingarelli,
  • Cherry Ng,
  • David J. Nice,
  • Stella Koch Ocker,
  • Ken D. Olum,
  • Timothy T. Pennucci,
  • Benetge B. P. Perera,
  • Polina Petrov,
  • Nihan S. Pol,
  • Henri A. Radovan,
  • Scott M. Ransom,
  • Paul S. Ray,
  • Joseph D. Romano,
  • Jessie C. Runnoe,
  • Alexander Saffer,
  • Shashwat C. Sardesai,
  • Ann Schmiedekamp,
  • Carl Schmiedekamp,
  • Kai Schmitz,
  • Brent J. Shapiro-Albert,
  • Xavier Siemens,
  • Joseph Simon,
  • Magdalena S. Siwek,
  • Sophia V. Sosa Fiscella,
  • Ingrid H. Stairs,
  • Daniel R. Stinebring,
  • Kevin Stovall,
  • Abhimanyu Susobhanan,
  • Joseph K. Swiggum,
  • Jacob Taylor,
  • Stephen R. Taylor,
  • Jacob E. Turner,
  • Caner Ünal,
  • Michele Vallisneri,
  • Rutger van Haasteren,
  • Sarah J. Vigeland,
  • Haley M. Wahl,
  • Caitlin A. Witt,
  • David Wright,
  • Olivia Young

摘要

The detection of a stochastic gravitational wave background by pulsar-timing arrays indicates the presence of a population of supermassive black hole binaries. Although the observed spectrum generally matches predictions for orbital evolution driven by gravitational-wave emission in circular orbits, there is a preference for a spectral turnover at the lowest observed frequencies, which may point to substantial hardening during a transition from early environmental influences to later stages dominated by emission. In the vicinity of these binaries, the ejection of stars or dark matter particles through gravitational three-body slingshots efficiently extracts orbital energy, leading to a low-frequency turnover in the spectrum. Here we model how the gravitational-wave spectrum depends on the initial inner galactic profile before scouring by binary ejections while accounting for a range of initial binary eccentricities. By analysing the NANOGrav 15-year data, we find that a parsec-scale galactic-centre density of around 106M pc3 is favoured across most of the parameter space, thus shedding light on the environmental effects that shape black hole evolution and the combined matter density near galaxy centres.