A Pilot Deep Survey for X-Ray Emission from fuvAGB Stars

TL;DR

This study presents a pilot survey detecting X-ray emissions from fuvAGB stars, revealing variability and high plasma temperatures that suggest accretion activity around companions rather than stellar coronae.

Contribution

First X-ray survey of fuvAGB stars showing variability and high-temperature plasma, proposing accretion onto companions as the emission source.

Findings

X-ray emission detected in 3 of 6 fuvAGB stars

X-ray flux varies on hour-long timescales

X-ray plasma temperatures are 35-160 million K

Abstract

We report the results of a pilot survey for X-ray emission from a newly discovered class of AGB stars with far-ultraviolet excesses (fuvAGB stars) using XMM-Newton and Chandra. We detected X-ray emission in 3 of 6 fuvAGB stars observed -- the X-ray fluxes are found to vary in a stochastic or quasi-periodic manner on roughly hour-long times-scales, and simultaneous UV observations using the Optical Monitor on XMM for these sources show similar variations in the UV flux. These data, together with previous studies, show that X-ray emission is found only in fuvAGB stars. From modeling the spectra, we find that the observed X-ray luminosities are ~(0.002-0.2 ) Lsun, and the X-ray emitting plasma temperatures are ~(35-160) x 10^6 K. The high X-ray temperatures argue against the emission arising in stellar coronae, or directly in an accretion shock, unless it occurs on a WD companion. However, none of the detected objects is a known WD-symbiotic star, suggesting that if WD companions are present, they are relatively cool (<20,000 K). In addition, the high X-ray luminosities specifically argue against emission originating in the coronae of main-sequence companions. We discuss several models for the X-ray emission and its variability and find that the most likely scenario for the origin of the X-ray (and FUV) emission involves accretion activity around a companion star, with confinement by strong magnetic fields associated with the companion and/or an accretion disk around it.