Chemically homogeneous evolution: a rapid population synthesis approach

Jeff Riley; Ilya Mandel; Pablo Marchant; Ellen Butler; Kaila Nathaniel; Coenraad Neijssel; Spencer Shortt; Alejandro Vigna-Gomez

doi:10.1093/mnras/stab1291

Chemically homogeneous evolution: a rapid population synthesis approach

Jeff Riley^*, Ilya Mandel, Pablo Marchant, Ellen Butler, Kaila Nathaniel, Coenraad Neijssel, Spencer Shortt, Alejandro Vigna-Gomez

^*Corresponding author for this work

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Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

We explore chemically homogeneous evolution (CHE) as a formation channel for massive merging binary black holes (BBHs). We develop methods to include CHE in a rapid binary population synthesis code, Compact Object Mergers: Population Astrophysics and Statistics (compas), which combines realistic models of binary evolution with cosmological models of the star formation history of the Universe. For the first time, we simultaneously explore conventional isolated binary star evolution under the same set of assumptions. This approach allows us to constrain population properties and make simultaneous predictions about the gravitational-wave detection rates of BBH mergers for the CHE and conventional formation channels. The overall mass distribution of detectable BBHs is consistent with existing gravitational-wave observations. We find that the CHE channel may yield up to of all gravitational-wave detections of BBH mergers coming from isolated binary evolution.

Original language	English
Journal	Monthly Notices of the Royal Astronomical Society
Volume	505
Issue number	1
Pages (from-to)	663-676
Number of pages	14
ISSN	0035-8711
DOIs	https://doi.org/10.1093/mnras/stab1291
Publication status	Published - 2 Jul 2021

Keywords

gravitational waves
stars: evolution
stars: massive
black hole mergers
binaries: close
EQUATION-OF-STATE
BLACK-HOLE MERGERS
MASSIVE STARS
DIFFERENT METALLICITIES
STELLAR EVOLUTION
PAIR-INSTABILITY
BINARY STARS
EXPLOSION
SUPERNOVAE
DYNAMICS

Access to Document

10.1093/mnras/stab1291

stab1291(1)Final published version, 4.88 MBLicence: CC BY

Cite this

Chemically homogeneous evolution : a rapid population synthesis approach. / Riley, Jeff; Mandel, Ilya; Marchant, Pablo; Butler, Ellen; Nathaniel, Kaila; Neijssel, Coenraad; Shortt, Spencer; Vigna-Gomez, Alejandro.

In: Monthly Notices of the Royal Astronomical Society, Vol. 505, No. 1, 02.07.2021, p. 663-676.

Research output: Contribution to journal › Journal article › Research › peer-review

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title = "Chemically homogeneous evolution: a rapid population synthesis approach",

abstract = "We explore chemically homogeneous evolution (CHE) as a formation channel for massive merging binary black holes (BBHs). We develop methods to include CHE in a rapid binary population synthesis code, Compact Object Mergers: Population Astrophysics and Statistics (compas), which combines realistic models of binary evolution with cosmological models of the star formation history of the Universe. For the first time, we simultaneously explore conventional isolated binary star evolution under the same set of assumptions. This approach allows us to constrain population properties and make simultaneous predictions about the gravitational-wave detection rates of BBH mergers for the CHE and conventional formation channels. The overall mass distribution of detectable BBHs is consistent with existing gravitational-wave observations. We find that the CHE channel may yield up to of all gravitational-wave detections of BBH mergers coming from isolated binary evolution.",

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AU - Riley, Jeff

AU - Mandel, Ilya

AU - Marchant, Pablo

AU - Butler, Ellen

AU - Nathaniel, Kaila

AU - Neijssel, Coenraad

AU - Shortt, Spencer

AU - Vigna-Gomez, Alejandro

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AB - We explore chemically homogeneous evolution (CHE) as a formation channel for massive merging binary black holes (BBHs). We develop methods to include CHE in a rapid binary population synthesis code, Compact Object Mergers: Population Astrophysics and Statistics (compas), which combines realistic models of binary evolution with cosmological models of the star formation history of the Universe. For the first time, we simultaneously explore conventional isolated binary star evolution under the same set of assumptions. This approach allows us to constrain population properties and make simultaneous predictions about the gravitational-wave detection rates of BBH mergers for the CHE and conventional formation channels. The overall mass distribution of detectable BBHs is consistent with existing gravitational-wave observations. We find that the CHE channel may yield up to of all gravitational-wave detections of BBH mergers coming from isolated binary evolution.

KW - gravitational waves

KW - stars: evolution

KW - stars: massive

KW - black hole mergers

KW - binaries: close

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KW - BLACK-HOLE MERGERS

KW - MASSIVE STARS

KW - DIFFERENT METALLICITIES

KW - STELLAR EVOLUTION

KW - PAIR-INSTABILITY

KW - BINARY STARS

KW - EXPLOSION

KW - SUPERNOVAE

KW - DYNAMICS

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JF - Royal Astronomical Society. Monthly Notices

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