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A triple star origin for T Pyx and other short-period recurrent novae

A triple star origin for T Pyx and other short-period recurrent novae
A triple star origin for T Pyx and other short-period recurrent novae

Recurrent novae are star systems in which a massive white dwarf accretes material at such a high rate that it undergoes thermonuclear runaways every 1-100 yr. They are the only class of novae in which the white dwarf can grow in mass, making some of these systems strong Type Ia supernova progenitor candidates. Almost all known recurrent novae are long-period (Porb ? 12h) binary systems in which the requisite mass supply rate can be provided by an evolved (sub-)giant donor star. However, at least two recurrent novae are short-period (Porb ? 3h) binaries in which mass transfer would normally be driven by gravitational radiation at rates three to four orders of magnitude smaller than required. Here, we show that the prototype of this class - T Pyxidis - has a distant proper motion companion and therefore likely evolved from a hierarchical triple star system. Triple evolution can naturally produce exotic compact binaries as a result of three-body dynamics, either by Kozai-Lidov eccentricity cycles in dynamically stable systems or via mass-loss-induced dynamical instabilities. By numerically evolving triple progenitors with physically reasonable parameters forward in time, we show explicitly that the inner binary can become so eccentric that mass transfer is triggered at periastron, driving the secondary out of thermal equilibrium. We suggest that short-period recurrent novae likely evolved via this extreme state, explaining their departure from standard binary evolution tracks.

binaries: close, novae, cataclysmic variables, proper motions
1365-2966
1895–1907
Knigge, C.
ac320eec-631a-426e-b2db-717c8bf7857e
Toonen, S.
957e428a-ca18-4f9f-8a92-ff1bc92451c9
Boekholt, T.C.N.
ab3032e3-1962-4c83-8cf2-2b1db78ca42d
Knigge, C.
ac320eec-631a-426e-b2db-717c8bf7857e
Toonen, S.
957e428a-ca18-4f9f-8a92-ff1bc92451c9
Boekholt, T.C.N.
ab3032e3-1962-4c83-8cf2-2b1db78ca42d

Knigge, C., Toonen, S. and Boekholt, T.C.N. (2022) A triple star origin for T Pyx and other short-period recurrent novae. Monthly Notices of the Royal Astronomical Society, 514 (2), 1895–1907. (doi:10.1093/mnras/stac1336).

Record type: Article

Abstract

Recurrent novae are star systems in which a massive white dwarf accretes material at such a high rate that it undergoes thermonuclear runaways every 1-100 yr. They are the only class of novae in which the white dwarf can grow in mass, making some of these systems strong Type Ia supernova progenitor candidates. Almost all known recurrent novae are long-period (Porb ? 12h) binary systems in which the requisite mass supply rate can be provided by an evolved (sub-)giant donor star. However, at least two recurrent novae are short-period (Porb ? 3h) binaries in which mass transfer would normally be driven by gravitational radiation at rates three to four orders of magnitude smaller than required. Here, we show that the prototype of this class - T Pyxidis - has a distant proper motion companion and therefore likely evolved from a hierarchical triple star system. Triple evolution can naturally produce exotic compact binaries as a result of three-body dynamics, either by Kozai-Lidov eccentricity cycles in dynamically stable systems or via mass-loss-induced dynamical instabilities. By numerically evolving triple progenitors with physically reasonable parameters forward in time, we show explicitly that the inner binary can become so eccentric that mass transfer is triggered at periastron, driving the secondary out of thermal equilibrium. We suggest that short-period recurrent novae likely evolved via this extreme state, explaining their departure from standard binary evolution tracks.

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stac1336 - Version of Record
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Accepted/In Press date: 27 April 2022
e-pub ahead of print date: 13 May 2022
Published date: 1 August 2022
Additional Information: Funding Information: This project was supported by funds from the European Research Council (ERC) Publisher Copyright: © 2022 The Author(s) 2022. Published by Oxford University Press on behalf of Royal Astronomical Society.
Keywords: binaries: close, novae, cataclysmic variables, proper motions

Identifiers

Local EPrints ID: 457973
URI: http://eprints.soton.ac.uk/id/eprint/457973
DOI: doi:10.1093/mnras/stac1336
ISSN: 1365-2966
PURE UUID: 566d4661-230a-4316-81b3-543f7f6792d6

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Date deposited: 23 Jun 2022 17:56
Last modified: 16 Mar 2024 17:48

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Contributors

Author: C. Knigge
Author: S. Toonen
Author: T.C.N. Boekholt

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