Mean opacities of a strongly magnetized high-temperature plasma

Suleimanov, V.; Mushtukov, Alexander A.; Ognev, I. S.; Doroshenko, V.; Werner, K.

doi:10.1093/mnras/stac2935

Cited by 6 publications

(3 citation statements)

References 46 publications

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“…In these cases, the surface magnetic fields determined from the AC emission properties (e.g., critical luminosity, CRSF, and maximum luminosity) are very different from (and most likely much stronger than) the dipole fields determined from torque models. However, recent studies (Suleimanov et al 2022) show that the high magnetic field increases the electron-positron pairs, which compensate the opacity reduction due to the high magnetic field, such that…”

Section: Multipole and Dipole Magnetic Fields Of Pulxsmentioning

confidence: 99%

Monte Carlo Simulations on Possible Collimation Effects of Outflows to Fan Beam Emission of Ultraluminous Accreting X-Ray Pulsars

Hou

You

et al. 2022

ApJ

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Pulsating ultraluminous X-ray sources (PULXs) are accreting pulsars with apparent X-ray luminosity exceeding 1039 erg s−1. We perform Monte Carlo simulations to investigate whether a high collimation effect (or strong beaming effect) is dominant in the presence of accretion outflows, for the fan beam emission of the accretion column of the neutron stars in PULXs. We show that the three nearby PULXs (RX J0209.6−7427, Swift J0243.6+6124, and SMC X-3), namely, the Three Musketeers here, have their main pulsed emission not strongly collimated even if strong outflows exist. This conclusion can be extended to the current sample of extragalactic PULXs, if accretion outflows are commonly produced from them. This means that the observed high luminosity of PULXs is indeed intrinsic, which can be used to infer the existence of very strong surface magnetic fields of ∼1013–14 G, possibly multipole fields. However, if strong outflows are launched from the accretion disks in PULXs as a consequence of disk spherization by radiation pressure, regular dipole magnetic fields of ∼1012 G may be required, comparable to that of the Three Musketeers, which have experienced large luminosity changes from well below their Eddington limit (2 × 1038 erg s−1 for an NS) to super-Eddington and whose maximum luminosity fills the luminosity gap between Galactic pulsars and extragalactic PULXs.

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Section: Multipole and Dipole Magnetic Fields Of Pulxsmentioning

confidence: 99%

Monte Carlo Simulations on Possible Collimation Effects of Outflows to Fan Beam Emission of Ultraluminous Accreting X-Ray Pulsars

Hou

You

et al. 2022

ApJ

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“…When the luminosity exceeds the critical value of ∼10 37 erg s −1 (Mushtukov et al 2015), the radiation-dominated shock inside the column decelerates the accretion flow, and the kinetic energy is converted to X-rays via the Comptonization of the seed photons emitted from the surface of the neutron star (Becker & Wolff 2005Odaka et al 2014). The power-law-like spectrum, accompanied by a cutoff feature, which is typical of X-ray pulsars, has been interpreted as a consequence of bulk and thermal Comptonization in the accretion column, with the substantial modification of scattering cross sections due to the presence of the magnetic field (Daugherty & Harding 1986;Mushtukov et al 2016;Schwarm et al 2017;Suleimanov et al 2022). Some previous studies have revealed that the model satisfactorily explains the X-ray spectra of X-ray pulsars (e.g., Wolff et al 2016;West et al 2017), based on the 1D radiative transfer equation.…”

Section: Introductionmentioning

confidence: 99%

Orbital- and Spin-phase Variability in the X-Ray Emission from the Accreting Pulsar Centaurus X-3

Tamba

Odaka

Tanimoto

et al. 2023

ApJ

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We present a time-resolved analysis using 39 ks NuSTAR observation data of the X-ray pulsar Centaurus X-3, covering an orbital-phase interval of Φ = 0.199–0.414. The orbital- and spin-phase variabilities are investigated through time-resolved spectra, light curves, and pulse profiles. The orbital-phase variability was due to the mixture of two comparable effects: intrinsic flux variability of ∼10% and obscuration by the clumpy stellar wind. The typical size and number density of the clumps are ∼9 × 1010 cm and ∼3 × 1012 cm−3, respectively. In the spin-phase-resolved analysis, we detected variations in the spectral features of the continuum, the Fe line, and the cyclotron resonance scattering feature (CRSF). The photon index ranged from 0.72 to 1.06, corresponding to the difference in the Comptonization optical depth by a factor of ∼1.6. The equivalent width and intensity of the Fe line had negative correlations with the continuum flux. The central energy and the strength of the CRSF increased at the pulse maximum. The former ranged from 26.0 to 28.7 keV, while the latter varied by a factor of ∼1.9. The pulse profile was double-peaked in the low-energy band, and it gradually shifted to being single-peaked with energy, indicating the existence of two distinct emission patterns, corresponding to the pencil and fan beams. Finally, we found that the pulse profiles were highly stable along the orbital phase, within a variation degree of ∼20%, which provides evidence of the highly stable accretion stream of the binary system.

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“…The theory of neutrino emission from bright XRPs requires the development of an accurate model of accretion column, which accounts for mechanisms of magnetic opacity (Suleimanov et al 2022(Suleimanov et al , 2023 L X L ν Luminosity, erg s -1 mass accretion rate, g s -1…”

Section: Introductionmentioning

confidence: 99%

Bright X-ray pulsars as sources of MeV neutrinos in the sky

Asthana¹,

Mushtukov

Dobrynina

et al. 2023

Monthly Notices of the Royal Astronomical Society

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High mass accretion rate onto strongly magnetised neutron stars results in the appearance of accretion columns supported by the radiation pressure and confined by the strong magnetic field of a star. At mass accretion rates above ∼1019 g s−1, accretion columns are expected to be advective. Under such conditions, a noticeable part of the total energy release can be carried away by neutrinos of a MeV energy range. Relying on a simple model of the neutrino luminosity of accreting strongly magnetised neutron stars, we estimate the neutrino energy fluxes expected from six ULX pulsars known up to date and three brightest Be X-ray transits hosting magnetised neutron stars. Despite the large neutrino luminosity expected in ULX pulsars, the neutrino energy flux from the Be X-ray transients of our Galaxy, SMC and LMC is dominant. However, the neutrino flux from the brightest X-ray transients is estimated to be below the isotropic background by two orders of magnitude at least, which makes impossible direct registration of neutrino emission from accreting strongly magnetised neutron stars nowadays.

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Mean opacities of a strongly magnetized high-temperature plasma

Cited by 6 publications

References 46 publications

Monte Carlo Simulations on Possible Collimation Effects of Outflows to Fan Beam Emission of Ultraluminous Accreting X-Ray Pulsars

Monte Carlo Simulations on Possible Collimation Effects of Outflows to Fan Beam Emission of Ultraluminous Accreting X-Ray Pulsars

Orbital- and Spin-phase Variability in the X-Ray Emission from the Accreting Pulsar Centaurus X-3

Bright X-ray pulsars as sources of MeV neutrinos in the sky

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