The Astrophysical Journal (Jan 2023)

Insight-HXMT Detections of Hard X-Ray Tails in Scorpius X-1

  • G. Q. Ding,
  • J. L. Qu,
  • L. M. Song,
  • Y. Huang,
  • S. Zhang,
  • Q. C. Bu,
  • M. Y. Ge,
  • X. B. Li,
  • L. Tao,
  • X. Ma,
  • Y. P. Chen,
  • L. Zhang,
  • W. M. Yan,
  • Y. L. Tuo,
  • Y. C. Fu,
  • S. H. Xiao,
  • Z. X. Yang,
  • H. X. Liu

DOI
https://doi.org/10.3847/1538-4357/accf91
Journal volume & issue
Vol. 950, no. 1
p. 69

Abstract

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Using the observations of the high-energy detector of the Hard X-ray Modulation Telescope (Insight-HXMT) for Scorpius X-1 from 2017 to 2020, we search for hard X-ray tails in the X-ray spectra in ∼30–200 keV. The hard X-ray tails are found throughout the Z -track on the hardness–intensity diagram, and the detected hard X-ray tails become hard and weak from the horizontal branch (HB), through the normal branch (NB), to the flaring branch (FB). Comparing the hard X-ray spectra of Insight-HXMT between Cyg X-1 and Sco X-1, it is concluded that the hard X-ray spectrum of Cyg X-1 shows a high-energy cutoff, implying a hot corona in it, but the high-energy cutoff is not seen in the hard X-ray spectrum of Sco X-1. From fitting the broadband spectrum of Sco X-1 in ∼2–200 keV, it is proposed that the hard X-ray tails in the HB and NB can be explained by the overall Comptonization COMPTB model, suggesting that the hard X-ray tails could have resulted from the Comptonization of the photons from the neutron star (NS) surface by the thermal electrons in the region between the NS and the disk and the energetic electrons in the freefall toward the NS in the converging flow onto the NS. However, this model cannot be responsible for the hard X-ray tails in the FB. Further study on the FB hard X-ray tails is needed.

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