Hot disk of the Swift J0243.6+6124 revealed by Insight-HXMT

Doroshenko, V.; N., Zhang, S.; Santangelo, A.; Ji, Long; Tsygankov, Sergey S.; Mushtukov, Alexander A.; Qu, L. J.; Ge, M. Y.; Chen, Y. P.; Bu, Q. C.; Cao, X. L.; Chang, Zhigang; Chen, G.; Chen, L.; Chen, T. X.; Chen, Y. B.; Cui, Wei; Deng, J. K.; Dong, Yongwei; Du, Y. Y.; Fu, M. X.; Gao, G. H.; H, Gao; Gao, Min; Gu, Y. D.; Guan, J.; Guo, Chengcheng; Han, Danxiang; Hu, W.; Huang, Y.; Jia, Haiqiang; Jia, S.; Jiang, Luhua; Jiang, Weichun; Jin, J.; Jin, Y. J.; Kong, L. D.; Li, B.; Li, C. K.; Li, G.; Li, M. S.; Li, T. P.; Li, W.; Li, X.; Li, X. B.; Li, Y. G.; Li, Zhangjian; Liang, X. H.; Liao, J. Y.; Liu, C. Z.; Liu, G. Q.; Liu, H. W.; Liu, S. Z.; Liu, X. J.; Liu, Y.; Liu, Y. N.; Lü, Bo; Lu, Fangjun; Lu, X. F.; Luo, T.; Ma, Xiang; Meng, Bin; Nang, Y.; Nie, J. Y.; Ou, G.; Sai, N.; Song, L. M.; Song, X. Y.; Sun, Luming; Tan, Y. H.; Tao, Lian; Tuo, You-Li; Wang, G. F.; Wang, J.; Wang, W. S.; Wang, Y. S.; Wen, Xiang-Yang; Wu, B. B.; Wu, Mei‐Hwan; Xiao, G. C.; Xiong, S. L.; Xu, He; Xu, Y. P.; Yang, Yijun; Yang, Jiawei; Yang, S.; Zhang, A. M.; Zhang, C. L.; Zhang, F.; Zhang, H. M.; Zhang, J.; Zhang, Q.; Zhang, T.; Zhang, W.; Zhang, W. Z.; Zhang, Y.; Zhang, Z.; Zhang, Z. L.; Zhao, H.; Zhao, Jianling; Zhao, X. F.; Zheng, S.; Zhu, Yajun; Zou, C. L.

doi:10.1093/mnras/stz2879

Cited by 55 publications

(79 citation statements)

References 29 publications

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“…WH18 also observed similar dependence of the pulse profiles on the X-ray luminosity using data from NICER and FERMI -GBM, however, the AstroSat data allowed us to probe into these profiles up to 150 keV using narrow energy bands. Luminosity dependence of the pulse profiles has also been observed in several other X-ray pulsars (see e.g., White et al 1983;Nagase 1989;Doroshenko et al 2020, and references therein).…”

Section: Evolution Of the Pulse Profilesmentioning

confidence: 56%

“…However, based on the spin evolution study of J0243 performed using HXMT data, they also suggested that the NS's magnetic field is ∼ 10 13 G. However, this estimate contrasts with that proposed by Jaisawal et al (2019), whose broad iron line (peaking at 6.67 keV) in NICER spectra requires a dipolar magnetic field in a narrow range between 10 11 G and 10 12 G if it is to originate in the accretion disc. The presence of a weakly magnetized neutron star is also supported by a sharp state transition of the timing and spectral properties of the source at super-Eddington accretion rates (Doroshenko et al 2020).…”

Section: Introductionmentioning

confidence: 88%

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AstroSat observations of the first Galactic ULX pulsar Swift J0243.6+6124

Beri

Naik

Singh

et al. 2020

Monthly Notices of the Royal Astronomical Society

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Swift J0243.6+6124, the first Galactic ultra-luminous X-ray pulsar, was observed during its 2017-2018 outburst with AstroSat at both sub- and super-Eddington levels of accretion with X-ray luminosities of LX ∼ 7 × 1037 and 6 × 1038 ergs−1, respectively. Our broadband timing and spectral observations show that X-ray pulsations at ${\sim } 9.85 \rm {s}$ have been detected up to 150 keV when the source was accreting at the super-Eddington level. The pulse profiles are a strong function of both energy and source luminosity, showing a double-peaked profile with pulse fraction increasing from ∼ $10{\%}$ at $1.65 \rm {keV}$ to 40–80 % at $70 \rm {keV}$. The continuum X-ray spectra are well-modeled with a high energy cut-off power law (Γ ∼ 0.6-0.7) and one or two blackbody components with temperatures of ∼ 0.35 $\rm {keV}$ and $1.2 \rm {keV}$, depending on the accretion level. No iron line emission is observed at sub-Eddington level, while a broad emission feature at around 6.9 keV is observed at the super-Eddington level, along with a blackbody radius ($121-142 \rm {km}$) that indicates the presence of optically thick outflows.

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Section: Evolution Of the Pulse Profilesmentioning

confidence: 56%

Section: Introductionmentioning

confidence: 88%

AstroSat observations of the first Galactic ULX pulsar Swift J0243.6+6124

Beri

Naik

Singh

et al. 2020

Monthly Notices of the Royal Astronomical Society

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show abstract

“…Recently, however, it was proposed that strong pulsations in ULXs appear in the case of a lucky combination between geometrical parameters of the accreting system (King & Lasota 2020). Another problematic point is related to bright transient X-ray pulsars, which do not show any evidence of beaming at high luminosity states (Tsygankov et al 2017;Doroshenko et al 2020). Additionally, strong beaming in ULXs implies a large number of unbeamed and even diluted sources.…”

Section: Introductionmentioning

confidence: 99%

Pulsating ULXs: large pulsed fraction excludes strong beaming

Mushtukov

Zwart

Tsygankov

et al. 2020

Monthly Notices of the Royal Astronomical Society

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The recent discovery of pulsating ultraluminous X-ray sources (ULXs) shows that the apparent luminosity of accreting neutron stars can exceed the Eddington luminosity by a factor of 100s. The relation between the actual and apparent luminosity is a key ingredient in theoretical models of ULXs, but it is still under debate. A typical feature of the discovered pulsating ULXs is a large pulsed fraction (PF). Using Monte Carlo simulations, we consider a simple geometry of accretion flow and test the possibility of simultaneous presence of a large luminosity amplification due the geometrical beaming and a high PF. We argue that these factors largely exclude each other and only a negligible fraction of strongly beamed ULX pulsars can show PF above 10 per cent. Discrepancy between this conclusion and current observations indicates that pulsating ULXs are not strongly beamed and their apparent luminosity is close to the actual one.

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“…X-ray pulsars, XRPs) has been made over the last years due to extraordinary technical capabilities of the currently operating X-ray observatories. As a result, the range of observable luminosities from such objects extended over nine orders of magnitude from L X ∼ 10 40 − 10 41 erg s −1 for pulsating ultra luminous Xray sources (Bachetti et al 2014;Fürst et al 2016;Israel et al 2017;Rodríguez Castillo et al 2020;Doroshenko et al 2020) to L X ∼ 10 32 − 10 33 erg s −1 for XRPs in quiescent state (see e.g., Campana et al 2002;Doroshenko et al 2014;Wijnands & Degenaar 2016;Tsygankov et al 2017b), allowing to study absolutely different regimes of accretion onto highly magnetized neutron stars (NSs). In addition to the improved technical characteristics, the flexibility in arrange-Corresponding author: A. Lutovinov aal@iki.rssi.ru ment for long-term monitoring campaigns played a major role.…”

Section: Introductionmentioning

confidence: 99%

SRG/ART-XC and NuSTAR observations of the X-ray pulsar GRO J1008-57 in the lowest luminosity state

Lutovinov,

Tsygankov,

Molkov

et al. 2021

Preprint

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We report results of the first broadband observation of the transient X-ray pulsar GRO J1008−57 performed in the quiescent state. Observations were conducted quasi-simultaneously with the Mikhail Pavlinsky ART-XC telescope on board SRG and NuSTAR right before the beginning of a Type I outburst. GRO J1008−57 was detected in the state with the lowest observed luminosity around several ×10 34 erg s −1 and consequently accreting from the cold disk. Timing analysis allowed to significantly detect pulsations during this state for the first time. The observed pulsed fraction of about 20% is, however, almost three times lower than in brighter states when the accretion proceeds through the standard disk. We traced the evolution of the broadband spectrum of the source on a scale of three orders of magnitude in luminosity and found that at the lowest luminosities the spectrum transforms into the double-hump structure similarly to other X-ray pulsars accreting at low luminosities (X Persei, GX 304-1, A 0535+262) reinforcing conclusion that this spectral shape is typical for these objects.

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Hot disk of the Swift J0243.6+6124 revealed by Insight-HXMT

Cited by 55 publications

References 29 publications

AstroSat observations of the first Galactic ULX pulsar Swift J0243.6+6124

AstroSat observations of the first Galactic ULX pulsar Swift J0243.6+6124

Pulsating ULXs: large pulsed fraction excludes strong beaming

SRG/ART-XC and NuSTAR observations of the X-ray pulsar GRO J1008-57 in the lowest luminosity state

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