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Constraining the evolution of cataclysmic variables via the masses and accretion rates of their underlying white dwarfs

Constraining the evolution of cataclysmic variables via the masses and accretion rates of their underlying white dwarfs
Constraining the evolution of cataclysmic variables via the masses and accretion rates of their underlying white dwarfs
We report on the masses (MWD), effective temperatures (⁠TeffTeff⁠), andsecular mean accretion rates (⁠⟨M˙⟩⟨M˙⟩⁠) of 43 cataclysmic variable (CV) white dwarfs, 42 of which were obtained from the combined analysis of their Hubble Space Telescope ultraviolet data with the parallaxes provided by the Early Third Data Release of the Gaia space mission, and one from the white dwarf gravitational redshift. Our results double the number of CV white dwarfs with an accurate mass measurement, bringing the total census to 89 systems. From the study of the mass distribution, we derive ⟨MWD⟩=0.81+0.16−0.20M⊙⟨MWD⟩=0.81−0.20+0.16M⊙⁠, in perfect agreement with previous results, and find no evidence of any evolution of the mass with orbital period. Moreover, we identify five systems with MWD < 0.5 M, which are most likely representative of helium-core white dwarfs, showing that these CVs are present in the overall population. We reveal the presence of an anticorrelation between the average accretion rates and the white dwarf masses for the systems below the 2−32−3 h period gap. Since ⟨M˙⟩⟨M˙⟩ reflects the rate of system angular momentum loss, this correlation suggests the presence of an additional mechanism of angular momentum loss that is more efficient at low white dwarf masses. This is the fundamental concept of the recently proposed empirical prescription of consequential angular momentum loss (eCAML) and our results provide observational support for it, although we also highlight how its current recipe needs to be refined to better reproduce the observed scatter in TeffTeff and ⟨M˙⟩⟨M˙⟩⁠, and the presence of helium-core white dwarfs.
astro-ph.SR
1365-2966
Pala, A. F.
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Gänsicke, B.T.
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Belloni, D.
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Parsons, S.G.
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Marsh, T.R.
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Schreiber, M.R.
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Breedt, E.
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Knigge, C.
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Sion, E.M.
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Szkody, P.
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Townsley, D.
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Bildsten, L.
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Boyd, D.
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Cook, M.J.
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Martino, D. De
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Godon, P.
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Kafka, S.
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Kouprianov, V.
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Long, K.S.
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Monard, B.
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Myers, G.
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Nelson, P.
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Nogami, D.
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Oksanen, A.
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Pickard, R.
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Poyner, G.
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Reichart, D. E.
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Perez, D. Rodriguez
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Shears, J.
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Stubbings, R.
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Toloza, O.
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Pala, A. F.
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Gänsicke, B.T.
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Belloni, D.
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Parsons, S.G.
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Marsh, T.R.
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Schreiber, M.R.
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Breedt, E.
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Knigge, C.
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Sion, E.M.
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Szkody, P.
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Townsley, D.
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Bildsten, L.
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Boyd, D.
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Cook, M.J.
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Martino, D. De
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Godon, P.
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Kafka, S.
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Kouprianov, V.
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Long, K.S.
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Monard, B.
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Myers, G.
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Nelson, P.
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Nogami, D.
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Oksanen, A.
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Pickard, R.
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Poyner, G.
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Reichart, D. E.
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Perez, D. Rodriguez
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Shears, J.
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Stubbings, R.
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Toloza, O.
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Pala, A. F., Gänsicke, B.T., Belloni, D., Parsons, S.G., Marsh, T.R., Schreiber, M.R., Breedt, E., Knigge, C., Sion, E.M., Szkody, P., Townsley, D., Bildsten, L., Boyd, D., Cook, M.J., Martino, D. De, Godon, P., Kafka, S., Kouprianov, V., Long, K.S., Monard, B., Myers, G., Nelson, P., Nogami, D., Oksanen, A., Pickard, R., Poyner, G., Reichart, D. E., Perez, D. Rodriguez, Shears, J., Stubbings, R. and Toloza, O. (2022) Constraining the evolution of cataclysmic variables via the masses and accretion rates of their underlying white dwarfs. Monthly Notices of the Royal Astronomical Society, 510 (4). (doi:10.1093/mnras/stab3449).

Record type: Article

Abstract

We report on the masses (MWD), effective temperatures (⁠TeffTeff⁠), andsecular mean accretion rates (⁠⟨M˙⟩⟨M˙⟩⁠) of 43 cataclysmic variable (CV) white dwarfs, 42 of which were obtained from the combined analysis of their Hubble Space Telescope ultraviolet data with the parallaxes provided by the Early Third Data Release of the Gaia space mission, and one from the white dwarf gravitational redshift. Our results double the number of CV white dwarfs with an accurate mass measurement, bringing the total census to 89 systems. From the study of the mass distribution, we derive ⟨MWD⟩=0.81+0.16−0.20M⊙⟨MWD⟩=0.81−0.20+0.16M⊙⁠, in perfect agreement with previous results, and find no evidence of any evolution of the mass with orbital period. Moreover, we identify five systems with MWD < 0.5 M, which are most likely representative of helium-core white dwarfs, showing that these CVs are present in the overall population. We reveal the presence of an anticorrelation between the average accretion rates and the white dwarf masses for the systems below the 2−32−3 h period gap. Since ⟨M˙⟩⟨M˙⟩ reflects the rate of system angular momentum loss, this correlation suggests the presence of an additional mechanism of angular momentum loss that is more efficient at low white dwarf masses. This is the fundamental concept of the recently proposed empirical prescription of consequential angular momentum loss (eCAML) and our results provide observational support for it, although we also highlight how its current recipe needs to be refined to better reproduce the observed scatter in TeffTeff and ⟨M˙⟩⟨M˙⟩⁠, and the presence of helium-core white dwarfs.

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2111.13706v1 - Author's Original
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Accepted/In Press date: 17 November 2021
e-pub ahead of print date: 27 November 2021
Published date: March 2022
Keywords: astro-ph.SR
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Identifiers

Local EPrints ID: 471728
URI: http://eprints.soton.ac.uk/id/eprint/471728
DOI: doi:10.1093/mnras/stab3449
ISSN: 1365-2966
PURE UUID: 9419d339-459e-4ec0-ba41-aed29ffb8d90
ORCID for S.G. Parsons: ORCID iD orcid.org/0000-0002-2713-6448

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Date deposited: 17 Nov 2022 17:36
Last modified: 16 Oct 2024 16:37

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Contributors

Author: A. F. Pala
Author: B.T. Gänsicke
Author: D. Belloni
Author: S.G. Parsons ORCID iD
Author: T.R. Marsh
Author: M.R. Schreiber
Author: E. Breedt
Author: C. Knigge
Author: E.M. Sion
Author: P. Szkody
Author: D. Townsley
Author: L. Bildsten
Author: D. Boyd
Author: M.J. Cook
Author: D. De Martino
Author: P. Godon
Author: S. Kafka
Author: V. Kouprianov
Author: K.S. Long
Author: B. Monard
Author: G. Myers
Author: P. Nelson
Author: D. Nogami
Author: A. Oksanen
Author: R. Pickard
Author: G. Poyner
Author: D. E. Reichart
Author: D. Rodriguez Perez
Author: J. Shears
Author: R. Stubbings
Author: O. Toloza

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