X-Ray Spectroscopy of the High-Mass X-Ray Binary Pulsar Centaurus X-3 Over Its Binary Orbit

Naik, Sachindra; Paul, Biswajit; Ali, Zulfikar

doi:10.1088/0004-637x/737/2/79

Cited by 57 publications

(65 citation statements)

References 44 publications

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“…A cyclotron resonance scattering feature at 28 keV and 30 keV has been detected in Cen X-3 with two BeppoSAX observations (Santangelo et al 1998;Burderi et al 2000). Suzaku observation of Cen X-3 covering a full binary orbit showed multiple extended dips with spectral characteristics similar to that of the source in eclipse, indicating the dips to be produced due to obscuration by dense matter which are structures in the outer region of the accretion disk (Naik, Paul & Ali 2011) LMC X-4 is a wind and disk fed persistent system in the Large Magellanic Cloud (LMC) which often shows X-ray flares sometimes with super Eddington luminosity (Levine, Rappaport & Zojcheski 2000;Moon, Eikenberry & Wasserman 2003). The source was found to show pe- (Bildsten et al 1997), a6 (Raichur & Paul 2010), a7 (Thompson & Rothschild 2009), b2 (Li, Rappaport & Epstein 1978); (White 1978), b3 (Levine, Rappaport & Zojcheski 2000), b4 (Pietrzyński et al 2013), c2 (Schreier et al 1972a), c3 (Val Baker, Norton & Quaintrell 2005, c4 (Primini, Rappaport & Joss 1977), c5 (Reynolds et al 1993), c6 (Levine et al 1993), c7 (Hilditch, Howarth & Harries 2005) d1 (Jones et al 1973), d2 (Clark et al 2002), d3 (Penny et al 1973), d4 , d5 (Ankay et al 2001) e2 (Becker et al 1977), e3 (Reynolds, Bell & Hilditch 1992), e4 (Parkes, Murdin & Mason 1978), (Falanga et al 2015), e5 (Mukherjee et al 2006 (Sguera et al 2005), g1 (Molkov et al 2003), g2 (Jain, Paul & Dutta 2009a), g3 (Vacca, Garmany & Shull 1996), g4 (Nespoli, Fabregat & Mennickent 2008), h0 (Romano et al 2011), h2 <...>…”

Section: Introductionmentioning

confidence: 78%

X-Ray Reprocessing: Through the Eclipse Spectra of High-mass X-Ray Binaries with XMM-Newton

Aftab¹,

Paul²,

Kretschmar³

2019

ApJS

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The study of X-ray reprocessing is one of the key diagnostic tools to probe the environment in X-ray binary systems. One difficult aspect of studying X-ray reprocessing is the presence of much brighter primary radiation from the compact star together with the reprocessed radiation. In contrast for eclipsing systems, the X-rays we receive during eclipse are only those produced by reprocessing of the emission from the compact star by the surrounding medium. We report results from a spectral study of the X-ray emission during eclipse and outside eclipse (when available) in 9 high mass X-ray binaries (HMXBs) with XMM-Newton EPIC pn to investigate different aspects of the stellar wind in these HMXBs. During eclipse the continuum component of the spectrum is reduced by a factor of ∼8-237, but the count-rate for 6.4 keV Iron emission line or complex of Iron emission lines in HMXBs are reduced by a smaller factor leading to large equivalent widths of the Iron emission lines. This indicates a large size for the line emission region, comparable to or larger than the companion star in these HMXB systems. However there are significant system to system differences. 4U 1538−52, in spite of having a large absorption column density, shows a soft emission component with comparable flux during the eclipse and out-of-eclipse phases. Emission from Hydrogen-like Iron has been observed in LMC X-4 for the first time, in the out-of-eclipse phase in one of the observations. Overall, we find significant differences in the eclipse spectrum of different HMXBs and also in their eclipse spectra against out-of-eclipse spectra.

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Section: Introductionmentioning

confidence: 78%

X-Ray Reprocessing: Through the Eclipse Spectra of High-mass X-Ray Binaries with XMM-Newton

Aftab¹,

Paul²,

Kretschmar³

2019

ApJS

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“…Observations performed with the gratings on board Chandra also show the presence of Doppler broadened Si xiii, Si xiv, and Fe xxv complexes caused by recombination in a photoionized plasma (Wojdowski et al 2003;Iaria et al 2005). It has been argued that the fluorescent lines originate relatively close to the NS (probably in the outer regions of the accretion disk), while the other lines are produced at greater distances from the NS in the wind of the massive companion (Iaria et al 2005;Naik et al 2011). The stellar wind velocity measured from these lines is significantly smaller than that expected for an O-type star, providing convincing indications for a strong perturbation of the wind by the NS X-ray radiation.…”

Section: Cen X-3mentioning

confidence: 99%

“…The spectral energy distribution also shows a remarkable dependence on the spin and orbital phase (see e.g. Suchy et al 2008;Raichur & Paul 2008;Naik et al 2011, and references therein).…”

Section: Cen X-3mentioning

confidence: 99%

A new model for the X-ray continuum of the magnetized accreting pulsars

Farinelli

Ferrigno

Bozzo

et al. 2016

A&A

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Context. Accreting highly magnetized pulsars in binary systems are among the brightest X-ray emitters in our Galaxy. Although a number of high-quality broad-band (0.1-100 keV) X-ray observations are available, the spectral energy distribution of these sources is usually investigated by adopting pure phenomenological models rather than models linked to the physics of accretion. Aims. In this paper, a detailed spectral study of the X-ray emission recorded from the high-mass X-ray binary pulsars Cen X-3, 4U 0115+63, and Her X-1 is carried out by using BeppoSAX and joined Suzaku +NuStar data, together with an advanced version of the compmag model, which provides a physical description of the high-energy emission from accreting pulsars, including the thermal and bulk Comptonization of cyclotron and bremsstrahlung seed photons along the neutron star accretion column.Methods. The compmag model is based on an iterative method for solving second-order partial differential equations, whose convergence algorithm has been improved and consolidated during the preparation of this paper. Results. Our analysis shows that the broad-band X-ray continuum of all considered sources can be self-consistently described by the compmag model. The cyclotron absorption features (not included in the model) can be accounted for by using Gaussian components. From the fits of the compmag model to the data we inferred the physical properties of the accretion columns in all sources, finding values reasonably close to those theoretically expected according to our current understanding of accretion in highly magnetized neutron stars.Conclusions. The updated version of the compmag model has been tailored to the physical processes that are known to occur in the columns of highly magnetized accreting neutron stars and it can thus provide a better understanding of the high-energy radiation from these sources. The availability of broad-band high-quality X-ray data, such as those provided by BeppoSAX in the past and currently from NuStar and other facilities, is crucial to fully exploit the potentialities of the model. The advent of the Astro-H mission, endowed with an unprecedented combination of high sensitivity and X-ray broad-band coverage, provides good perspectives to improve our understanding of accretion onto highly magnetized neutron stars through physical models like the one adopted here.

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“…Depending on the statistics of the data and the energy coverage, it proved necessary in several cases to complement these relatively simple spectral models with the additions of broad Gaussian components (see, e.g., Klochkov et al 2007;Suchy et al 2008) and/or partial covering absorbers (Naik et al 2011(Naik et al , 2013Naik & Jaisawal 2015). Furthermore, the cyclotron resonant scattering of electrons in the high magnetic field of the NS is known to produce characteristic absorption lines that have been observed in several of these systems and included in the spectral fits by using either Gaussian or Lorentzian profiles (see, e.g., Walter et al 2015, for a recent review).…”

Section: Introductionmentioning

confidence: 99%

Glancing through the accretion column of EXO 2030+375

Ferrigno

Pjanka

Bozzo

et al. 2016

A&A

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Context. The current generation of X-ray instruments is progressively revealing more and more details about the complex magnetic field topology and the geometry of the accretion flows in highly magnetized accretion powered pulsars. Aims. We took advantage of the large collecting area and good timing capabilities of the EPIC cameras on-board XMM-Newton to investigate the accretion geometry onto the magnetized neutron star hosted in the high mass X-ray binary EXO 2030+375 during the rise of a source Type-I outburst in 2014. Methods. We carried out a timing and spectral analysis of the XMM-Newton observation as function of the neutron star spin phase. We used a phenomenological spectral continuum model comprising the required fluorescence emission lines. Two neutral absorption components are present: one covering fully the source and one only partially. The same analysis was also carried out on two Suzaku observations of the source performed during outbursts in 2007 and 2012, to search for possible spectral variations at different luminosities.Results. The XMM-Newton data caught the source at an X-ray luminosity of 2 × 10 36 erg s −1 and revealed the presence of a narrow dip-like feature in its pulse profile that was never reported before. The width of this feature corresponds to about one hundredth of the neutron star spin period. From the results of the phase-resolved spectral analysis we suggest that this feature can be ascribed to the self-obscuration of the accretion stream passing in front of the observer line of sight. We inferred from the Suzaku observation carried out in 2007 that the self-obscuration of the accretion stream might produce a significantly wider feature in the neutron star pulsed profile at higher luminosities ( 2 × 10 37 erg s −1 ). Conclusions. This discovery allowed us to derive additional constraints on the physical properties of the accretion flow in this object at relatively small distances from the neutron star surface. The presence of such a narrow dip-like feature in the pulse profile is so far unique among all known high mass X-ray binaries hosting strongly magnetized neutron stars.

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X-Ray Spectroscopy of the High-Mass X-Ray Binary Pulsar Centaurus X-3 Over Its Binary Orbit

Cited by 57 publications

References 44 publications

X-Ray Reprocessing: Through the Eclipse Spectra of High-mass X-Ray Binaries with XMM-Newton

X-Ray Reprocessing: Through the Eclipse Spectra of High-mass X-Ray Binaries with XMM-Newton

A new model for the X-ray continuum of the magnetized accreting pulsars

Glancing through the accretion column of EXO 2030+375

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