Puzzling blue dips in the black hole candidate Swift J1357.2 − 0933, from ULTRACAM, SALT, ATCA, Swift, and NuSTAR

We present rapid, multiwavelength photometry of the low-mass X-ray binary Swift J1357.2-0933 during its 2017 outburst. Using several sets of quasi-simultaneous ULTRACAM/NTT (optical), NuSTAR (X-ray), XRT/Swift (X-ray), SALT (optical), and ATCA (radio) observations taken during outburst decline, we confirm the frequent optical dipping that has previously been noted both in outburst and in quiescence. We also find: (1) that the dip frequency decreases as the outburst decays, similar to what was seen in the previous outburst, (2) that the dips produce a shape similar to that in binary systems with partial disc occultations, (3) that the source becomes significantly bluer during these dips, indicating an unusual geometry compared to other LMXB dippers, and (4) that dip superposition analysis confirms the lack of an X-ray response to the optical dips. These very unusual properties appear to be unique to Swift J1357.2−0933, and are likely the result of a high binary inclination, as inferred from features such as its very low outburst X-ray luminosity. From this analysis as well as X-ray/optical timing correlations, we suggest a model with multicomponent emission/absorption features with differing colours. This could include the possible presence of a sporadically occulted jet base and a recessed disc. This source still hosts many puzzling features, with consequences for the very faint X-ray transients population.

[1]  P. Casella,et al.  Radio-loudness in black hole transients: evidence for an inclination effect , 2018, Monthly Notices of the Royal Astronomical Society.

[2]  B. Liu,et al.  A MODEL FOR THE CORRELATION OF HARD X-RAY INDEX WITH EDDINGTON RATIO IN BLACK HOLE X-RAY BINARIES , 2012, 1212.1770.

[3]  M. Nowak,et al.  Low-Luminosity States of the Black Hole Candidate GX 339–4. II. Timing Analysis , 1998, astro-ph/9812180.

[4]  R. Hynes The Optical and Ultraviolet Spectral Energy Distributions of Short-Period Black Hole X-Ray Transients in Outburst , 2004, astro-ph/0412531.

[5]  Eric W. Greisen,et al.  AIPS, the VLA, and the VLBA , 2003 .

[6]  P. G. Jonker,et al.  American Astronomical Society Meeting Abstracts , 2011 .

[7]  T. Shahbaz,et al.  Swift J1357.2−0933: a massive black hole in the Galactic thick disc , 2015, 1509.05412.

[8]  B. Savage,et al.  A survey of interstellar H I from L-alpha absorption measurements. II , 1978 .

[9]  T. A. Lister,et al.  Gaia Data Release 2. Summary of the contents and survey properties , 2018, 1804.09365.

[10]  C. Brocksopp,et al.  Rapid infrared flares in GRS 1915+105: evidence for infrared synchrotron emission , 1997, astro-ph/9707317.

[11]  J. Miller-Jones,et al.  A clean sightline to quiescence: multiwavelength observations of the high Galactic latitude black hole X-ray binary Swift J1357.2−0933 , 2015, 1512.01941.

[12]  T. Shahbaz,et al.  A Black Hole Nova Obscured by an Inner Disk Torus , 2013, Science.

[13]  D. A. García-Hernández,et al.  University of Birmingham The Fourteenth Data Release of the Sloan Digital Sky Survey: , 2017 .

[14]  Douglas P. Finkbeiner,et al.  MEASURING REDDENING WITH SLOAN DIGITAL SKY SURVEY STELLAR SPECTRA AND RECALIBRATING SFD , 2010, 1012.4804.

[15]  David A. H. Buckley,et al.  Completion and commissioning of the Southern African Large Telescope , 2006, SPIE Astronomical Telescopes + Instrumentation.

[16]  Gaia Collaboration,et al.  The Gaia mission , 2016, 1609.04153.

[17]  P. Giommi,et al.  The Swift X-Ray Telescope , 1999 .

[18]  Optical Precursors to Black Hole X-Ray Binary Outbursts: An Evolving Synchrotron Jet Spectrum in Swift J1357.2-0933 , 2017, 1707.05814.

[19]  F. Bauer,et al.  BlackCAT: A catalogue of stellar-mass black holes in X-ray transients , 2015, 1510.08869.

[20]  V. S. Dhillon,et al.  ULTRACAM: An Ultra-Fast, Triple-Beam CCD Camera for High-Speed Astrophysics , 2008 .

[21]  B. Scott Gaudi,et al.  Achieving Better Than 1 Minute Accuracy in the Heliocentric and Barycentric Julian Dates , 2010, 1005.4415.

[22]  J. Mathis,et al.  The relationship between infrared, optical, and ultraviolet extinction , 1989 .

[23]  V. S. Dhillon,et al.  ULTRACAM: an ultrafast, triple-beam CCD camera for high-speed astrophysics , 2007 .

[24]  Michael A. C. Johnson,et al.  Gaia Data Release 2 distances and peculiar velocities for Galactic black hole transients , 2018, Monthly Notices of the Royal Astronomical Society.

[25]  Robert A. Shaw,et al.  Astronomical data analysis software and systems IV : meeting held at Baltimore, Maryland, 25-28 September 1994 , 1995 .

[26]  Michael P. Smith,et al.  Prime focus imaging spectrograph for the Southern African large telescope: operational modes , 2003, SPIE Astronomical Telescopes + Instrumentation.

[27]  V. S. Dhillon,et al.  Furiously fast and red: sub-second optical flaring in V404 Cyg during the 2015 outburst peak , 2016, 1603.04461.

[28]  J. P. Osborne,et al.  Methods and results of an automatic analysis of a complete sample of Swift-XRT observations of GRBs , 2008, 0812.3662.

[29]  T. Shahbaz,et al.  Evidence for quiescent synchrotron emission in the black hole X-ray transient Swift J1357.2–0933 , 2013, 1307.0659.

[30]  A. Kong,et al.  NuSTAR and Swift Observations of Swift J1357.2–0933 During an Early Phase of Its 2017 Outburst , 2017, 1712.02804.

[31]  Paul M. Brunet,et al.  The Gaia mission , 2013, 1303.0303.

[32]  Shuang-Nan Zhang,et al.  Multiwavelength light-curve evolution of Swift J1357.2−0933 during its 2011 outburst , 2015, 1511.07667.

[33]  P. A. Charles,et al.  First science with the Southern African Large Telescope: peering at the accreting polar caps of the eclipsing polar SDSS J015543.40+002807.2 , 2006 .

[34]  D. Steeghs,et al.  VLT spectroscopy of the black hole candidate Swift J1357.2−0933 in quiescence , 2015, 1503.08874.

[35]  P. Gandhi,et al.  The black hole X-ray transient Swift J1357.2–0933 as seen with Swift and NuSTAR during its 2017 outburst , 2019, Monthly Notices of the Royal Astronomical Society.

[36]  P. Gandhi,et al.  Jet spectral breaks in black hole X-ray binaries , 2012, 1211.1655.

[37]  Yunjin Kim,et al.  Nuclear Spectroscopic Telescope Array (NuSTAR) Mission , 2013, 2013 IEEE Aerospace Conference.

[38]  Michael A. C. Johnson,et al.  Prospecting for periods with LSST – low-mass X-ray binaries as a test case , 2018, Monthly Notices of the Royal Astronomical Society.

[39]  E. Fomalont,et al.  The VLBA Calibrator Survey—VCS1 , 2002, astro-ph/0201414.

[40]  An elevation of 0.1 light-seconds for the optical jet base in an accreting Galactic black hole system , 2017, 1710.09838.

[41]  W. Welsh,et al.  On the Reliability of Cross‐Correlation Function Lag Determinations in Active Galactic Nuclei , 1999, astro-ph/9911112.

[42]  K. Mason,et al.  The structure of low-mass X-ray binaries , 1985 .

[43]  Alan A. Wells,et al.  The Swift Gamma-Ray Burst Mission , 2004, astro-ph/0405233.

[44]  R. Wijnands,et al.  An X-ray view of the very faint black hole X-ray transient Swift J1357.2–0933 during its 2011 outburst , 2013, 1308.4326.

[45]  D. Ciardi,et al.  KEPLER OBSERVATIONS OF THREE PRE-LAUNCH EXOPLANET CANDIDATES: DISCOVERY OF TWO ECLIPSING BINARIES AND A NEW EXOPLANET , 2010, 1010.4106.

[46]  R. Wijnands,et al.  Multiwavelength spectral evolution during the 2011 outburst of the very faint X-ray transient Swift J1357.2−0933 , 2012, 1207.5805.

[47]  Durham,et al.  NuSTAR SPECTROSCOPY OF MULTI-COMPONENT X-RAY REFLECTION FROM NGC 1068 , 2014, 1411.0670.

[48]  P. D'Avanzo,et al.  A VARIABLE MID-INFRARED SYNCHROTRON BREAK ASSOCIATED WITH THE COMPACT JET IN GX 339–4 , 2011, 1109.4143.

[49]  Steven M. Crawford,et al.  PySALT: the SALT science pipeline , 2010, Astronomical Telescopes + Instrumentation.

[50]  R Edelson,et al.  The Discrete Correlation Function: a New Method for Analyzing Unevenly Sampled Variability Data , 1988 .