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Implications of pulsar timing array observations for <i>LISA</i> detections of massive black hole binaries

Nathan Steinle, H. Middleton, C. J. Moore, Siyuan Chen, Antoine Klein, G. Pratten, R. Buscicchio, Eliot Finch, A. Vecchio

2023Monthly Notices of the Royal Astronomical Society17 citationsDOIOpen Access PDF

Abstract

ABSTRACT Pulsar timing arrays (PTAs) and the Laser Interferometer Space Antenna (LISA) will open complementary observational windows on massive black hole binaries (MBHBs), i.e. with masses in the range ${\sim} 10^6\!-\!10^{10}\, \rm M_{\odot }$. While PTAs may detect a stochastic gravitational wave background from a population of MBHBs, during operation LISA will detect individual merging MBHBs. To demonstrate the profound interplay between LISA and PTAs, we estimate the number of MBHB mergers that one can expect to observe with LISA by extrapolating direct observational constraints on the MBHB merger rate inferred from PTA data. For this, we postulate that the common signal observed by PTAs (and consistent with the increased evidence recently reported) is an astrophysical background sourced by a single MBHB population. We then constrain the LISA detection rate, $\mathcal {R}$, in the mass–redshift space by combining our Bayesian-inferred merger rate with LISA’s sensitivity to spin-aligned, inspiral–merger–ringdown waveforms. Using an astrophysically informed formation model, we predict a $95{{\, \rm per\, cent}}$ upper limit on the detection rate of $\mathcal {R} \lt 134\, {\rm yr}^{-1}$ for binaries with total masses in the range $10^7\!-\!10^8\, \rm M_{\odot }$. For higher masses, i.e. ${\gt} 10^8\, \rm M_{\odot }$, we find $\mathcal {R} \lt 2\, (1)\, \mathrm{yr}^{-1}$ using an astrophysically informed (agnostic) formation model, rising to $11 \, (6)\, \mathrm{yr}^{-1}$ if the LISA sensitivity bandwidth extends down to 10−5 Hz. Forecasts of LISA science potential with PTA background measurements should improve as PTAs continue their search.

Topics & Concepts

PhysicsAstrophysicsPulsarGravitational wave backgroundGravitational waveRedshiftPopulationSensitivity (control systems)Parameter spaceBlack hole (networking)AstronomyStatisticsGalaxyElectronic engineeringEngineeringRouting (electronic design automation)Routing protocolMathematicsSociologyDemographyComputer networkComputer scienceLink-state routing protocolPulsars and Gravitational Waves ResearchCosmology and Gravitation TheoriesRadio Astronomy Observations and Technology
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