Title: Disentangling the NIR/optical emission of the black hole XTE J1650-500 during outburst Authors: P.A. Curran (1), S. Chaty (1), J.A. Zurita Heras (2) ((1) AIM/CEA-Saclay, (2) FACe -- U. Paris Diderot)
While the sources of X-ray and radio emission in the different states of low-mass X-ray binaries are relatively well understood, the origin of the near-infrared (NIR) and optical emission is more often debated. It is likely that the NIR/optical flux originates from an amalgam of different emission regions, because it occurs at the intersecting wavelengths of multiple processes. We aim to identify the NIR/optical emission region(s) of one such low-mass X-ray binary and black hole candidate, XTE J1650-500, via photometric, timing, and spectral analyses. We present unique NIR/optical images and spectra, obtained with the ESO-New Technology Telescope, during the peak of the 2001 outburst of XTE J1650-500. The data suggest that the NIR/optical flux is due to a combination of emission mechanisms including a significant contribution from X-ray reprocessing and, at early times in the hard state, a relativistic jet that is NIR/radio dim compared to similar sources. The jet of XTE J1650-500 is relatively weak compared to that of other black hole low-mass X-ray binaries, possibly because we observe as it is being "turned off" or quenched at the state transition. While there are several outliers to the radio--X-ray correlation of the hard state of low-mass X-ray binaries, XTE J1650-500 is the first example of an outlier to the NIR/optical--X-ray correlation.
Astronomers have identified the smallest known black hole. The puny object weighs only 3.8 times the Sun's mass and spans just 24 kilometres across. The black hole is believed to have formed from the collapse of a massive star when it ran out of fuel. Astronomers are not sure what the smallest possible mass is for black holes formed this way, but they estimate that it is somewhere between 1.7 and 2.7 times the Sun's mass. Less massive objects are expected to collapse into dense neutron stars instead of black holes.