Abstract
ABSTRACT AM CVn systems are ultra-compact, hydrogen-depleted, and helium-rich, accreting binaries with degenerate or semidegenerate donors. We report the discovery of five new eclipsing AM CVn systems with orbital periods of 61.5, 55.5, 53.3, 37.4, and 35.4 min. These systems were discovered by searching for deep eclipses in the Zwicky Transient Facility (ZTF) light curves of white dwarfs selected using Gaia parallaxes. We obtained phase-resolved spectroscopy to confirm that all systems are AM CVn binaries, and we obtained high-speed photometry to confirm the eclipse and characterize the systems. The spectra show double-peaked H e lines but also show metals, including K and Zn, elements that have never been detected in AM CVn systems before. By modelling the high-speed photometry, we measured the mass and radius of the donor star, potentially constraining the evolutionary channel that formed these AM CVn systems. We determined that the average mass of the accreting white dwarf is ≈0.8 M⊙, and that the white dwarfs in long-period systems are hotter than predicted by recently updated theoretical models. The donors have a high entropy and are a factor of ≈2 more massive compared to zero-entropy donors at the same orbital period. The large donor radius is most consistent with H e-star progenitors, although the observed spectral features seem to contradict this. The discovery of five new eclipsing AM CVn systems is consistent with the known observed AM CVn space density and estimated ZTF recovery efficiency.
Highlights
AM CVn systems are ultra-compact accreting binaries with degenerate or semi-degenerate, hydrogen-depleted and helium-rich donors
We present the search of Zwicky Transient Facility (ZTF) lightcurves to find new eclipsing white dwarf binaries and the discovery of five new AM CVn systems and their characterization
We did not detect any significant deviations from the eclipse arrival time, except for system for ZTFJ0407−00
Summary
AM CVn systems are ultra-compact accreting binaries with degenerate or semi-degenerate, hydrogen-depleted and helium-rich donors. Thousands of AM CVn systems are expected to be present in our Galaxy, but their intrinsic faintness limits the known population to ≈ 60 AM CVn systems (see Ramsay et al 2018 for a recent compilation) Because of their compactness and short orbital periods, AM CVn stars are an excellent tool to study accretion physics under extreme conditions (e.g. Kotko et al 2012; Coleman et al 2018; Cannizzo & Ramsay 2019; Oyang et al 2021). The mass of the He-shell becomes larger and the time between flashes longer as the systems evolve to longer orbital periods This can result in a very energetic ‘final-flash’ which can be dynamical and eject material from the white dwarf, dubbed a ‘.Ia’ transient (Shen et al 2010). Shen (2015) suggest that all double white dwarfs merge (because of friction with ejected material in a nova eruption), and double white dwarfs do not form AM CVn systems
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