The Hot Components of AM CVn Helium Cataclysmics

TL;DR

This study uses synthetic spectral analysis of far ultraviolet data to determine the properties of hot components in AM CVn systems, revealing significant WD contributions and updated temperature estimates.

Contribution

It provides the first detailed spectral analysis of multiple AM CVn systems using the BINSYN code with parallax-based distances, updating WD temperature estimates and accretion rates.

Findings

WDs significantly contribute to FUV flux in several systems

ES Ceti's WD likely has a small disk, not direct impact accretion

Updated WD temperatures: ES Ceti ~40,000K, GP Com ~14,800K

Abstract

We present the results of a multi-component synthetic spectral analysis of the archival far ultraviolet spectra of the hot components of several AM CVn double degenerate interacting binaries with known distances from trigonometric parallaxes. Our analysis was carried out using the code BINSYN (Linnell & Hubeny 1996) which takes into account the donor companion star, the shock front which forms at the disk edge and the FUV and NUV energy distribution. We fixed the distance of each system at its parallax-derived value and adopted appropriate values of orbital inclination and white dwarf mass. We find that the accretion-heated "DO/DB" WDs are contributing significantly to the FUV flux in four of the systems (ES Ceti, CR Boo, V803 Cen, HP Lib, GP Com). In two of the systems, GP Com and ES Ceti, the WD dominates the FUV/NUV flux. We present model-derived accretion rates which agree with the low end of the range of accretion rates derived earlier from black body fits over the entire spectral energy distribution. We find that the WD in ES Ceti is very likely not a direct impact accretor but has a small disk. The WD in ES Ceti has $T_{eff} \sim 40,000 \pm 10,000$K. This is far cooler than the previous estimate of Espaillat et al.(2005). We find that the WD in GP Com has $T_{eff} = 14,800 \pm500$K, which is hotter than the previously estimated temperature of 11,000K. We present a comparison between our empirical results and current theoretical predictions for these systems.