Variability as a Predictor for the Hard-to-soft State Transition in GX 339−4

Creators: Lucchini, Matteo¹; Ten Have, Marina¹; Wang, Jingyi¹; Homan, Jeroen^{2, 3}; Kara, Erin¹; Adegoke, Oluwashina⁴; Connors, Riley⁵; Dauser, Thomas⁶; Garcia, Javier⁴; Mastroserio, Guglielmo⁷; Ingram, Adam^{8, 9}; van der Klis, Michiel¹⁰; König, Ole⁶; Lewin, Collin¹; Mallick, Labani^{4, 11, 12}; Nathan, Edward^{4, 8}; O'Neill, Patrick⁹; Panagiotou, Christos¹; Piotrowska, Joanna⁴; Uttley, Phil¹⁰

1. Massachusetts Institute of Technology
2. Eureka Scientic, Inc., 2452 Delmer Street, Oakland, CA 94602, USA
3. Netherlands Institute for Space Research
4. California Institute of Technology
5. Villanova University
6. University of Erlangen-Nuremberg
7. Osservatorio Astronomico di Cagliari
8. University of Oxford
9. Newcastle University
10. University of Amsterdam
11. University of Manitoba
12. Canadian Institute for Theoretical Astrophysics

Abstract

During the outbursts of black hole X-ray binaries (BHXRBs), their accretion flows transition through several states. The source luminosity rises in the hard state, dominated by nonthermal emission, before transitioning to the blackbody-dominated soft state. As the luminosity decreases, the source transitions back into the hard state and fades to quiescence. This picture does not always hold, as ≈40% of the outbursts never leave the hard state. Identifying the physics that govern state transitions remains one of the outstanding open questions in black hole astrophysics. In this paper we present an analysis of archival RXTE data of multiple outbursts of GX 339−4. We compare the properties of the X-ray variability and time-averaged energy spectrum and demonstrate that the variability (quantified by the power spectral hue) systematically evolves ≈10–40 days ahead of the canonical state transition (quantified by a change in spectral hardness); no such evolution is found in hard-state-only outbursts. This indicates that the X-ray variability can be used to predict if and when the hard-to-soft state transition will occur. Finally, we find a similar behavior in 10 outbursts of four additional BHXRBs with more sparse observational coverage. Based on these findings, we suggest that state transitions in BHXRBs might be driven by a change in the turbulence in the outer regions of the disk, leading to a dramatic change in variability. This change is only seen in the spectrum days to weeks later, as the fluctuations propagate inwards toward the corona.

Copyright and License

Original content from this work may be used under the terms of the Creative Commons Attribution 4.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.

Acknowledgement

We are thankful to the anonymous reviewer, whose comments have improved the quality and clarity of the manuscript. M.L., G.M., J.W., E.K., and J.A.G. acknowledge support from NASA ADAP grant 80NSSC17K0515. J.W. acknowledges support from the NASA FINNEST Graduate Fellowship, under grant 80NSSC22K1596. A.I. acknowledges support from the Royal Society. M.K. acknowledges support by the NWO Spinoza Prize. O.K. acknowledges funding by the Deutsches Zentrum für Luft-und Raumfahrt, contract 50 QR 2103. This research has made use of data and software provided by the High Energy Astrophysics Science Archive Research Center (HEASARC), which is a service of the Astrophysics Science Division at NASA/GSFC.

Software References

Heasoft (Nasa High Energy Astrophysics Science Archive Research Center (Heasarc), 2014)), XSPEC (Arnaud 1996), Chromos (Gardenier & Uttley 2018), Stingray (Huppenkothen et al. 2019, 2019), PCACorr García et al. 2014, Numpy (Harris et al. 2020), Matplotlib (Hunter 2007), Scipy (Virtanen et al. 2020).

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