2018
DOI: 10.1093/mnras/sty1372
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The reflection component in the average and heartbeat spectra of the black hole candidate IGR J17091-3642 during the 2016 outburst

Abstract: We present simultaneous NuSTAR and Swift observations of the black hole transient IGR J17091-3642 during its 2016 outburst. By jointly fitting six NuSTAR and four Swift spectra, we found that during this outburst the source evolves from the hard to the hard/soft intermediate and back to the hard state, similar to the 2011 outburst. Unlike in the previous outburst, in this case we observed both a broad emission and an moderately broad absorption line in our observations. Our fits favour an accretion disc with a… Show more

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Cited by 18 publications
(15 citation statements)
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References 64 publications
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“…We note that during the 2016 outburst multiple NuS-TAR observations of IGR J17091-3624 were taken, however we note that they were not simultaneous with respect to the XMM-Newton observations and therefore cannot be used to model the high-energy band. We find in the XMM-Newton spectra signatures of reflection via the presence of a broad Fe line, similar to those present in the NuSTAR data (Xu et al 2017;Wang et al 2018). However, in this paper, due to the lack of simultaneous hard X-ray observations, we use a simple Gaussian model to fit the line rather than a reflection component (see Section 3) and focus for the search of absorbers in the spectra.…”
Section: Observations and Data Reductionsupporting
confidence: 56%
See 1 more Smart Citation
“…We note that during the 2016 outburst multiple NuS-TAR observations of IGR J17091-3624 were taken, however we note that they were not simultaneous with respect to the XMM-Newton observations and therefore cannot be used to model the high-energy band. We find in the XMM-Newton spectra signatures of reflection via the presence of a broad Fe line, similar to those present in the NuSTAR data (Xu et al 2017;Wang et al 2018). However, in this paper, due to the lack of simultaneous hard X-ray observations, we use a simple Gaussian model to fit the line rather than a reflection component (see Section 3) and focus for the search of absorbers in the spectra.…”
Section: Observations and Data Reductionsupporting
confidence: 56%
“…Their best-fit model indicates an inclination angle of the accretion disc of ∼ 30 • − 40 • . Wang et al (2018) support these conclusions in their analysis of the same data, although their reflection model requires an abundance of Fe=(3.5 ± 0.3) compared to (1.77<Fe<2.95) reported by Xu et al (2017). However, they pointed out that model assumptions, such as the photon-index of the incident continuum spectrum and the density profile, strongly affect the iron abundance.…”
Section: Introductionmentioning
confidence: 51%
“…Apart from the thermal and nonthermal components, emissionand absorption-line features have also been widely observed in BHXBs, especially the broad emission line centered at 6.4-7 keV (e.g., Laor 1991;Miller 2007;García et al 2015;Wang et al 2018). As the most prominent feature of disk reflection, such emission line is produced when the nonthermal/hard emission illuminates the accretion disk (Lightman & White 1988;George & Fabian 1991;García et al 2014;Dauser et al 2014), though the illuminating source has also been attributed to the surface emission or the boundary layer in neutron star X-ray binaries (e.g., Ross & Fabian 2005;Cackett et al 2010;Miller et al 2015;Wang et al 2019).…”
Section: Introductionmentioning
confidence: 99%
“…The mass of MAXI J1348-630 has been reported to be 9.1 +1.6 −1.2 M by Jana et al ( 2020) and 13 ± 2 M by Tominaga et al (2020), further rectified to be 11 ± 2 M by Lamer et al (2020). Using equation 3 from Wang et al (2018) and the correction factor from Kubota et al (1998) for the soft state diskbb normalisation, we find the black hole mass to be ∼ 11.6 − 19.4 M . We note that the calculated mass from the NuSTAR diskbb normalisation is likely to be incorrect, due to lack of <3 keV spectra in NuSTAR.…”
Section: Discussionmentioning
confidence: 55%