Swift Observations of Hard X-ray Emitting White Dwarfs in Symbiotic Stars

TL;DR

This study reports Swift observations of four symbiotic star systems with accreting white dwarfs emitting hard X-rays above 20 keV, revealing their spectral properties, absorption features, and variability, indicating non-magnetic white dwarf accretion processes.

Contribution

First detailed Swift X-ray analysis of hard X-ray emitting symbiotic white dwarfs, characterizing their spectra, absorption, and variability, suggesting non-magnetic accretion mechanisms.

Findings

Hard X-ray emission detected up to >50 keV in RT Cru.

Spectra consistent with optically thin thermal plasma plus Fe lines.

Variability attributed to changes in local absorption.

Abstract

The X-ray emission from most accreting white dwarfs (WDs) in symbiotic binary stars is quite soft. Several symbiotic WDs, however, produce strong X-ray emission at energies greater than ~20 keV. The Swift BAT instrument has detected hard X-ray emission from 4 such accreting WDs in symbiotic stars: RT Cru, T CrB, CD -57 3057, and CH Cyg. In one case (RT Cru), Swift detected X-rays out to greater than 50 keV at a > 5 sigma confidence level. Combining data from the XRT and BAT detectors, we find that the 0.3-150 keV spectra of RT Cru, T CrB, and CD -57 3057 are well described by emission from a single-temperature, optically thin thermal plasma, plus an unresolved 6.4-6.9 keV Fe line complex. The X-ray spectrum of CH Cyg contains an additional bright soft component. For all 4 systems, the spectra suffer high levels of absorption from material that both fully and partially covers the source of hard X-rays. The XRT data did not show any of the rapid, periodic variations that one would expect if the X-ray emission were due to accretion onto a rotating, highly magnetized WD. The X-rays were thus more likely from the accretion-disk boundary layer around a massive, non-magnetic WD in each binary. The X-ray emission from RT Cru varied on timescales of a few days. This variability is consistent with being due to changes in the absorber that partially covers the source, suggesting localized absorption from a clumpy medium moving into the line of sight. The X-ray emission from CD -57 3057 and T CrB also varied during the 9 months of Swift observations, in a manner that was also consistent with variable absorption.