Massive Stellar Triples Leading to Sequential Binary Black Hole Mergers in the Field

Alejandro Vigna-Gomez; Silvia Toonen; Enrico Ramirez-Ruiz; Nathan W. C. Leigh; Jeff Riley; Carl-Johan Haster

doi:10.3847/2041-8213/abd5b7

Massive Stellar Triples Leading to Sequential Binary Black Hole Mergers in the Field

Alejandro Vigna-Gomez^*, Silvia Toonen, Enrico Ramirez-Ruiz, Nathan W. C. Leigh, Jeff Riley, Carl-Johan Haster

^*Corresponding author for this work

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Research output: Contribution to journal › Letter › Research › peer-review

23 Citations (Scopus)

Abstract

Stellar triples with massive stellar components are common and can lead to sequential binary black hole mergers. Here we outline the evolution toward these sequential mergers and explore these events in the context of gravitational-wave astronomy and the pair-instability mass gap. We find that binary black hole mergers in the pair-instability mass gap can be of triple origin and therefore are not exclusively formed in dense dynamical environments. We discuss the sequential merger scenario in the context of the most massive gravitational-wave sources detected to date: GW170729 and GW190521. We propose that the progenitor of GW170729 is a low-metallicity field triple. We support the premise that GW190521 could not have been formed in the field. We conclude that triple stellar evolution is fundamental to the understanding of gravitational-wave sources and likely other energetic transients as well.

Original language	English
Article number	19
Journal	Astrophysical Journal Letters
Volume	907
Issue number	1
Number of pages	12
ISSN	2041-8205
DOIs	https://doi.org/10.3847/2041-8213/abd5b7
Publication status	Published - Jan 2021

Keywords

Astrophysical black holes
PRESUPERNOVA EVOLUTION
COMPACT OBJECTS
RATES
STARS
SINGLE

Access to Document

10.3847/2041-8213/abd5b7

https://arxiv.org/pdf/2010.13669.pdf

Cite this

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title = "Massive Stellar Triples Leading to Sequential Binary Black Hole Mergers in the Field",

abstract = "Stellar triples with massive stellar components are common and can lead to sequential binary black hole mergers. Here we outline the evolution toward these sequential mergers and explore these events in the context of gravitational-wave astronomy and the pair-instability mass gap. We find that binary black hole mergers in the pair-instability mass gap can be of triple origin and therefore are not exclusively formed in dense dynamical environments. We discuss the sequential merger scenario in the context of the most massive gravitational-wave sources detected to date: GW170729 and GW190521. We propose that the progenitor of GW170729 is a low-metallicity field triple. We support the premise that GW190521 could not have been formed in the field. We conclude that triple stellar evolution is fundamental to the understanding of gravitational-wave sources and likely other energetic transients as well.",

keywords = "Astrophysical black holes, PRESUPERNOVA EVOLUTION, COMPACT OBJECTS, RATES, STARS, SINGLE",

author = "Alejandro Vigna-Gomez and Silvia Toonen and Enrico Ramirez-Ruiz and Leigh, {Nathan W. C.} and Jeff Riley and Carl-Johan Haster",

year = "2021",

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AU - Vigna-Gomez, Alejandro

AU - Toonen, Silvia

AU - Ramirez-Ruiz, Enrico

AU - Leigh, Nathan W. C.

AU - Riley, Jeff

AU - Haster, Carl-Johan

PY - 2021/1

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AB - Stellar triples with massive stellar components are common and can lead to sequential binary black hole mergers. Here we outline the evolution toward these sequential mergers and explore these events in the context of gravitational-wave astronomy and the pair-instability mass gap. We find that binary black hole mergers in the pair-instability mass gap can be of triple origin and therefore are not exclusively formed in dense dynamical environments. We discuss the sequential merger scenario in the context of the most massive gravitational-wave sources detected to date: GW170729 and GW190521. We propose that the progenitor of GW170729 is a low-metallicity field triple. We support the premise that GW190521 could not have been formed in the field. We conclude that triple stellar evolution is fundamental to the understanding of gravitational-wave sources and likely other energetic transients as well.

KW - Astrophysical black holes

KW - PRESUPERNOVA EVOLUTION

KW - COMPACT OBJECTS

KW - RATES

KW - STARS

KW - SINGLE

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