Abstract
ABSTRACT For a long time XMMU J010331.7−730144 was proposed as a high-mass X-ray binary candidate based on its X-ray properties, however, its optical behaviour was unclear – in particular previous observations did not reveal key Balmer emission lines. In this paper, we report on optical and X-ray variability of the system. XMMU J010331.7–730144 has been monitored with the Optical Gravitational Lensing Experiment (OGLE) in the I and V bands for the past 9 yr where it has shown extremely large amplitude outbursts separated by long periods of low-level flux. During its most recent optical outburst we obtained spectra with the Southern African Large Telescope (SALT) where, for the first time, the H α line is seen in emission, confirming the Be nature of the optical companion. The OGLE colour–magnitude diagrams also exhibit a distinct loop that is explained by changes in mass-loss from the Be star and mass outflow in its disc. In the X-rays, XMMU J010331.7−730144 has been monitored by the Neil Gehrels Swift Observatory through the S-CUBED programme. The X-ray flux throughout the monitoring campaign shows relatively low values for a typical Be/X-ray binary system. We show, from the analysis of the optical data, that the variability is due to the Be disc density and opacity changing rather than its physical extent as a result of efficient truncation by the NS. The relatively low X-ray flux can then be explained by the neutron star normally accreting matter at a low rate due to the small radial extent of the Be disc.
Highlights
Be stars are early-type, non-supergiant stars of B spectral class that display, or have displayed Balmer emission lines, at some point in time, in their optical spectra (Collins 1987)
This deduction from the relationship between the magnitude and colour follows from the fact that as the disc grows in size, the Be disc/star system gets brighter while the red continuum increases
In the edge-on scenario, as the disc grows in size the system reddens and gets dimmer, since the flaring disc obscures the light from the Be star
Summary
Be stars are early-type, non-supergiant stars of B spectral class that display, or have displayed Balmer emission lines, at some point in time, in their optical spectra (Collins 1987). The emission lines originate from the matter which makes up the circumstellar disc around the B star. The formation of the disc has been a subject of scrutiny over the years and is thought to be due to a combination of the rapid rotation of the star and non-radial pulsations When a compact object is in orbit around a Be star, the system is referred to as a Be X-ray binary. Be X-ray binaries (BeXBs) make up the largest subclass of high mass X-ray binaries (HMXBs), with 49 per cent of the total population consisting of them (Coleiro & Chaty 2013). The interaction of the compact object, primarily a neutron star (NS), with the circumstellar disc results in accretion of matter leading to X-ray outbursts. For a general review of BeXBs (see Reig 2011)
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