Models of AM CVn star outbursts

TL;DR

This paper models outbursts in AM CVn stars using an adapted dwarf-nova disc instability framework, revealing the importance of helium composition and variable mass transfer in shaping their complex light-curves.

Contribution

It demonstrates that helium-rich AM CVn outbursts can be explained by an adapted disc instability model, emphasizing the role of variable irradiation and additional mechanisms for superoutbursts.

Findings

Helium-dominated discs respond to thermal-viscous instability similarly to hydrogen discs.

AM CVn outbursts can be reproduced with an adapted dwarf-nova model.

Variable irradiation of the secondary influences outburst behavior.

Abstract

Outbursting AM CVn stars exhibit outbursts similar to those observed in different types of dwarf novae. Their light-curves combine the characteristic features of SU UMa, ER UMa, Z Cam, and WZ Sge-type systems but also show a variety of properties never observed in dwarf novae. The compactness of AM CVn orbits and their unusual chemical composition make these systems valuable testbeds for outburst models. We aim for a better understanding of the role of helium in the accretion disc instability mechanism, testing the model for dwarf novae outbursts in the case of AM CVn stars, and aim to explain the outburst light-curves of these ultra-compact binaries. We calculated the properties of the hydrogen-free AM CVn stars using our previously developed numerical code adapted to the different chemical composition of these systems and supplemented with formulae accounting for mass transfer rate variations, additional sources of the disc heating, and the primary's magnetic field. We discovered how helium-dominated discs react to the thermal-viscous instability and were able to reproduce various features of the outburst cycles in the light-curves of AM CVn stars. The AM CVn outbursts can be explained by the suitably adapted dwarf-nova disc instability model but, as in the case of its application to hydrogen-dominated cataclysmic variables, one has to resort to additional mechanisms to account for the observed superoutbursts, dips, cycling states, and standstills. We show that the enhanced mass-transfer rate, due presumably to variable irradiation of the secondary, must not only be taken into account but is a determining factor that shapes AM CVn star outbursts. The cause of the variable secondary's irradiation has yet to be understood; the best candidate is the precession of a tilted/warped disc.