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The black hole mass function across cosmic times. I. Stellar black holes and light seed distribution

The black hole mass function across cosmic times. I. Stellar black holes and light seed distribution
The black hole mass function across cosmic times. I. Stellar black holes and light seed distribution

This is the first paper in a series aimed at modeling the black hole (BH) mass function, from the stellar to the intermediate to the (super)massive regime. In the present work, we focus on stellar BHs and provide an ab initio computation of their mass function across cosmic times; we mainly consider the standard, and likely dominant, production channel of stellar-mass BHs constituted by isolated single/binary star evolution. Specifically, we exploit the state-of-the-art stellar and binary evolutionary code SEVN, and couple its outputs with redshift-dependent galaxy statistics and empirical scaling relations involving galaxy metallicity, star formation rate and stellar mass. The resulting relic mass function as a function of the BH mass m • features a rather flat shape up to m • ≈ 50 M o˙ and then a log-normal decline for larger masses, while its overall normalization at a given mass increases with decreasing redshift. We highlight the contribution to the local mass function from isolated stars evolving into BHs and from binary stellar systems ending up in single or binary BHs. We also include the distortion on the mass function induced by binary BH mergers, finding that it has a minor effect at the high-mass end. We estimate a local stellar BH relic mass density of ρ • ≈ 5 × 107 M o˙ Mpc-3, which exceeds by more than two orders of magnitude that in supermassive BHs; this translates into an energy density parameter Ω• ≈ 4 × 10-4, implying that the total mass in stellar BHs amounts to ≲1% of the local baryonic matter. We show how our mass function for merging BH binaries compares with the recent estimates from gravitational wave observations by LIGO/Virgo, and discuss the possible implications for dynamical formation of BH binaries in dense environments like star clusters. We address the impact of adopting different binary stellar evolution codes (SEVN and COSMIC) on the mass function, and find the main differences to occur at the high-mass end, in connection with the numerical treatment of stellar binary evolution effects. We highlight that our results can provide a firm theoretical basis for a physically motivated light seed distribution at high redshift, to be implemented in semi-analytic and numerical models of BH formation and evolution. Finally, we stress that the present work can constitute a starting point to investigate the origin of heavy seeds and the growth of (super)massive BHs in high-redshift star-forming galaxies, that we will pursue in forthcoming papers.

0004-637X
56
Sicilia, Alex
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Lapi, Andrea
126b5f87-60fa-4a57-8b84-802d5ffb1f17
Boco, Lumen
93c3f9ff-ba52-468f-b627-bc6cdae83e8f
Spera, Mario
20342606-c16b-494e-8c89-f063a616652f
Di Carlo, Ugo N.
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Mapelli, Michela
b9997189-658b-4740-b0d5-05e4780170bd
Shankar, Francesco
b10c91e4-85cd-4394-a18a-d4f049fd9cdb
Alexander, David M.
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Bressan, Alessandro
7394a006-f281-4ec5-8f0b-ba17271af3ea
Danese, Luigi
f582fc09-7892-45a8-af7c-4db2211df5cd
Sicilia, Alex
ba1791e8-fece-4057-abef-096de33a5757
Lapi, Andrea
126b5f87-60fa-4a57-8b84-802d5ffb1f17
Boco, Lumen
93c3f9ff-ba52-468f-b627-bc6cdae83e8f
Spera, Mario
20342606-c16b-494e-8c89-f063a616652f
Di Carlo, Ugo N.
6c26b476-ea66-4074-bd03-388144b95bc1
Mapelli, Michela
b9997189-658b-4740-b0d5-05e4780170bd
Shankar, Francesco
b10c91e4-85cd-4394-a18a-d4f049fd9cdb
Alexander, David M.
a11921e8-9f30-4906-b15f-7f2e7c0ed8a7
Bressan, Alessandro
7394a006-f281-4ec5-8f0b-ba17271af3ea
Danese, Luigi
f582fc09-7892-45a8-af7c-4db2211df5cd

Sicilia, Alex, Lapi, Andrea, Boco, Lumen, Spera, Mario, Di Carlo, Ugo N., Mapelli, Michela, Shankar, Francesco, Alexander, David M., Bressan, Alessandro and Danese, Luigi (2022) The black hole mass function across cosmic times. I. Stellar black holes and light seed distribution. The Astrophysical Journal, 924 (2), 56, [56]. (doi:10.3847/1538-4357/ac34fb).

Record type: Article

Abstract

This is the first paper in a series aimed at modeling the black hole (BH) mass function, from the stellar to the intermediate to the (super)massive regime. In the present work, we focus on stellar BHs and provide an ab initio computation of their mass function across cosmic times; we mainly consider the standard, and likely dominant, production channel of stellar-mass BHs constituted by isolated single/binary star evolution. Specifically, we exploit the state-of-the-art stellar and binary evolutionary code SEVN, and couple its outputs with redshift-dependent galaxy statistics and empirical scaling relations involving galaxy metallicity, star formation rate and stellar mass. The resulting relic mass function as a function of the BH mass m • features a rather flat shape up to m • ≈ 50 M o˙ and then a log-normal decline for larger masses, while its overall normalization at a given mass increases with decreasing redshift. We highlight the contribution to the local mass function from isolated stars evolving into BHs and from binary stellar systems ending up in single or binary BHs. We also include the distortion on the mass function induced by binary BH mergers, finding that it has a minor effect at the high-mass end. We estimate a local stellar BH relic mass density of ρ • ≈ 5 × 107 M o˙ Mpc-3, which exceeds by more than two orders of magnitude that in supermassive BHs; this translates into an energy density parameter Ω• ≈ 4 × 10-4, implying that the total mass in stellar BHs amounts to ≲1% of the local baryonic matter. We show how our mass function for merging BH binaries compares with the recent estimates from gravitational wave observations by LIGO/Virgo, and discuss the possible implications for dynamical formation of BH binaries in dense environments like star clusters. We address the impact of adopting different binary stellar evolution codes (SEVN and COSMIC) on the mass function, and find the main differences to occur at the high-mass end, in connection with the numerical treatment of stellar binary evolution effects. We highlight that our results can provide a firm theoretical basis for a physically motivated light seed distribution at high redshift, to be implemented in semi-analytic and numerical models of BH formation and evolution. Finally, we stress that the present work can constitute a starting point to investigate the origin of heavy seeds and the growth of (super)massive BHs in high-redshift star-forming galaxies, that we will pursue in forthcoming papers.

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Published date: 10 January 2022
Additional Information: Publisher Copyright: © 2022. The Author(s). Published by the American Astronomical Society..

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Local EPrints ID: 455862
URI: http://eprints.soton.ac.uk/id/eprint/455862
ISSN: 0004-637X
PURE UUID: bdd48793-fa61-4af3-9d40-a7ee54903cd0

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Date deposited: 07 Apr 2022 16:32
Last modified: 11 Nov 2024 18:35

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Contributors

Author: Alex Sicilia
Author: Andrea Lapi
Author: Lumen Boco
Author: Mario Spera
Author: Ugo N. Di Carlo
Author: Michela Mapelli
Author: David M. Alexander
Author: Alessandro Bressan
Author: Luigi Danese

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