Resolving SLX 1744-299 and SLX 1744-300 in the hard X-ray band: implications for their ultracompact nature

Abstract

Persistent, low-luminosity low-mass X-ray binaries (LMXBs) offer a unique opportunity to study accretion in this poorly understood regime, as well as to unveil new members of the ultracompact X-ray binary (UCXB) family, characterised by orbital periods (P orb) shorter than 80 min. We report on a NuSTAR archival observation that, for the first time above 10 keV, spatially resolves the Galactic Centre pair SLX 1744-299 and SLX 1744-300. We find SLX 1744-300 to be slightly brighter, with a flux ratio of 1.15, increasing to 1.3 when extrapolated to 0.5-10 keV. Both the timing (root-mean-square variability) and spectral properties (well described in both cases by a thermal Comptonisation model) indicate that the systems were in the hard state. The two sources, however, display markedly different behaviour throughout the observation. SLX 1744-299 shows a gradual flux decline consistent with a decrease in the mass-accretion rate, whereas SLX 1744-300 remains steady but exhibits two short-recurrence Type-I X-ray bursts indicative of mixed H/He burning. Combining our results with previously reported upper limits on the distance, we derive low persistent X-ray luminosities of L X 1.1×1036 erg s-1 and L X 2.6×1036 erg s-1 (3-78 keV) for SLX 1744-299 and SLX 1744-300, respectively. The corresponding mass-accretion rates, when compared with the critical values from the disc instability model, favour P orb 90 min and P orb 105-155 min. Although both limits are formally compatible with the UCXB regime, the case of SLX 1744-299 appears significantly more compelling, also considering the previously reported intermediate-duration burst.