High-Speed Photometry of Gaia14aae: An Eclipsing AM CVn That Challenges   Formation Models

M. J. Green; T. R. Marsh; D. T. H. Steeghs; T. Kupfer; R. P. Ashley,; S. Bloemen; E. Breedt; H. C. Campbell; A. Chakpor; C. M. Copperwheat; V. S.; Dhillon; G. Hallinan; L. K. Hardy; J. J. Hermes; P. Kerry; S. P. Littlefair,; J. Milburn; S. G. Parsons; N. Prasert; J. van Roestel; D. I. Sahman; and N.; Singh

arXiv:1802.00499·astro-ph.SR·February 21, 2018

High-Speed Photometry of Gaia14aae: An Eclipsing AM CVn That Challenges Formation Models

M. J. Green, T. R. Marsh, D. T. H. Steeghs, T. Kupfer, R. P. Ashley,, S. Bloemen, E. Breedt, H. C. Campbell, A. Chakpor, C. M. Copperwheat, V. S., Dhillon, G. Hallinan, L. K. Hardy, J. J. Hermes, P. Kerry, S. P. Littlefair,, J. Milburn, S. G. Parsons, N. Prasert, J. van Roestel

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TL;DR

Gaia14aae, an eclipsing AM CVn binary, provides precise donor mass measurements challenging existing formation models, suggesting a complex evolutionary history possibly involving helium-burning stars or evolved cataclysmic variables.

Contribution

First high-speed photometry of Gaia14aae enabling precise donor mass measurement and challenging current AM CVn formation theories.

Findings

01

Donor mass and radius do not match white dwarf or helium star evolution predictions.

02

System's properties align with evolved cataclysmic variable models, but require additional processes.

03

Updated ephemeris corrects previous timing anomalies.

Abstract

AM CVn-type systems are ultra-compact, hydrogen-deficient accreting binaries with degenerate or semi-degenerate donors. The evolutionary history of these systems can be explored by constraining the properties of their donor stars. We present high-speed photometry of Gaia14aae, an AM CVn with a binary period of 49.7 minutes and the first AM CVn in which the central white dwarf is fully eclipsed by the donor star. Modelling of the lightcurves of this system allows for the most precise measurement to date of the donor mass of an AM CVn, and relies only on geometric and well-tested physical assumptions. We find a mass ratio $q = M_{2} / M_{1} = 0.0287 \pm 0.0020$ and masses $M_{1} = 0.87 \pm 0.02 M_{⊙}$ and $M_{2} = 0.0250 \pm 0.0013 M_{⊙}$ . We compare these properties to the three proposed channels for AM CVn formation. Our measured donor mass and radius do not fit with the contraction that is…

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Taxonomy

TopicsAstronomy and Astrophysical Research · Gamma-ray bursts and supernovae · Astro and Planetary Science