A Redshifted Inner Disk Atmosphere and Transient Absorbers in the Ultra-Compact Neutron Star X-ray Binary 4U 1916-053

Abstract

The very small accretion disks in ultra-compact X-ray binaries (UCXBs) are special laboratories in which to study disk accretion and outflows. We report on three sets of new (250 ks total) and archival (50 ks) Chandra/HETG observations of the "dipping" neutron-star X-ray binary 4U 1916-053, which has an orbital period of P 50~minutes. We find that the bulk of the absorption in all three spectra originates in a disk atmosphere that is redshifted by v 220-290 km s-1, corresponding to the gravitational redshift at radius of R 1200 GM/c2. This shift is present in the strongest, most highly ionized lines (Si XIV and Fe XXVI), with a significance of 5σ. Absorption lines observed during dipping events (typically associated with the outermost disk) instead display no velocity shifts and serve as a local standard of rest, suggesting that the redshift is intrinsic to an inner disk atmosphere and not due to radial motion in the galaxy or a kick. In two spectra, there is also evidence of a more strongly redshifted component that would correspond to a disk atmosphere at R 70 GM/c2; this component is significant at the 3σ level. Finally, in one spectrum, we find evidence of disk wind with a blue shift of v = -1700+1700-1200 km s-1. If real, this wind would require magnetic driving.