Accretion Geometry of GX 339–4 in the Hard State: AstroSat View

• Published in: The Astrophysical journal Vol. 972; no. 1; pp. 20 - 30
• Main Authors: Chand, Swadesh, Dewangan, Gulab C., Zdziarski, Andrzej A., Bhattacharya, Dipankar, Mithun, N. P. S., Vadawale, Santosh V.
• Format: Journal Article
• Language: English
• Published: Philadelphia The American Astronomical Society 01.09.2024; IOP Publishing
• Subjects: Black holes; Blackbody; Broadband; Corona; Emission spectra; Emissions; Frequency analysis; Geometry; High energy astrophysics; Low-mass x-ray binary stars; Luminosity; Outbursts; Soft x rays; Spectral analysis; Spectrum analysis; Stellar mass black holes; X ray binaries; X ray reflection; X ray stars; X-ray astronomy; X-ray binary stars; X-ray transient sources; X-rays
• ISSN: 0004-637X; 1538-4357
• DOI: 10.3847/1538-4357/ad5a88

We perform broadband (0.7–100 keV) spectral analysis of five hard state observations of the low-mass black hole X-ray binary GX 339–4 taken by AstroSat during the rising phase of three outbursts from 2019 to 2022. We find that the outburst in 2021 was the only successful/full outburst, while the source was unable to make the transition to the soft state during the other two outbursts in 2019 and 2022. Our spectral analysis employs two different model combinations, requiring two separate Comptonizing regions and their associated reflection components and soft X-ray excess emission. The harder Comptonizing component dominates the overall bolometric luminosity, while the softer one remains relatively weak. Our spectral fits indicate that the disk evolves with the source luminosity, where the inner disk radius decreases with increasing luminosity. However, the disk remains substantially truncated throughout all the observations at the source luminosity of ∼2%–8%× of the Eddington luminosity. We note that our assumption of the soft X-ray excess emission as disk blackbody may not be realistic, and this kind of soft excess may arise due the nonhomogeneity in the disk/corona geometry. Our temporal analysis deriving the power density spectra suggests that the break frequency increases with the source luminosity. Furthermore, our analysis demonstrates a consistency between the inner disk radii estimated from the break frequency of the power density spectra and those obtained from the reflection modeling, supporting the truncated disk geometry in the hard state.