222 research outputs found
Radiation and matter interaction in strongmagnetic field of accreting neutron stars
Siirretty Doriast
Propagating mass accretion rate fluctuations in X-ray binaries under the influence of viscous diffusion
Many statistical properties of X-ray aperiodic variability from accreting
compact objects can be explained by the propagating fluctuations model applied
to the accretion disc. The mass accretion rate fluctuations originate from
variability of viscosity, which arises at every radius and causes local
fluctuations of the density. The fluctuations diffuse through the disc and
result in local variability of the mass accretion rate, which modulates the
X-ray flux from the inner disc in the case of black holes, or from the surface
in the case of neutron stars. A key role in the theoretical explanation of fast
variability belongs to the description of the diffusion process. The
propagation and evolution of the fluctuations is described by the diffusion
equation, which can be solved by the method of Green functions. We implement
Green functions in order to accurately describe the propagation of fluctuations
in the disc. For the first time we consider both forward and backward
propagation. We show that (i) viscous diffusion efficiently suppress
variability at time scales shorter than the viscous time, (ii) local
fluctuations of viscosity affect the mass accretion rate variability both in
the inner and the outer parts of accretion disc, (iii) propagating fluctuations
give rise not only to hard time lags as previously shown, but also produce soft
lags at high frequency similar to those routinely attributed to reprocessing,
(iv) deviation from the linear rms-flux relation is predicted for the case of
very large initial perturbations. Our model naturally predicts bumpy power
spectra.Comment: 20 pages, 17 figures, accepted for publication in MNRA
Compton scattering S-matrix and cross section in strong magnetic field
Compton scattering of polarized radiation in a strong magnetic field is
considered. The recipe for calculation of the scattering matrix elements, the
differential and total cross sections based on quantum electrodynamic (QED)
second order perturbation theory is presented for the case of arbitrary initial
and final Landau level, electron momentum along the field and photon momentum.
Photon polarization and electron spin state are taken into account. The correct
dependence of natural Landau level width on the electron spin state is taken
into account in general case of arbitrary initial photon momentum for the first
time. A number of steps in calculations were simplified analytically making the
presented recipe easy-to-use. The redistribution functions over the photon
energy, momentum and polarization states are presented and discussed. The paper
generalizes already known results and offers a basis for accurate calculation
of radiation transfer in strong -field, for example, in strongly magnetized
neutron stars.Comment: 26 pages, 12 figures, accepted for publication in Phys. Rev.
Electron-positron pairs in hot plasma of accretion column in bright X-ray pulsars
The luminosity of X-ray pulsars powered by accretion onto magnetized neutron
stars covers a wide range over a few orders of magnitude. The brightest X-ray
pulsars recently discovered as pulsating ultraluminous X-ray sources reach
accretion luminosity above which exceeds the
Eddington value more than by a factor of ten. Most of the energy is released
within small regions in the vicinity of magnetic poles of accreting neutron
star - in accretion columns. Because of the extreme energy release within a
small volume accretion columns of bright X-ray pulsars are ones of the hottest
places in the Universe, where the internal temperature can exceed 100 keV.
Under these conditions, the processes of creation and annihilation of
electron-positron pairs can be influential but have been largely neglected in
theoretical models of accretion columns. In this letter, we investigate
properties of a gas of electron-positron pairs under physical conditions
typical for accretion columns. We argue that the process of pairs creation can
crucially influence both the dynamics of the accretion process and internal
structure of accretion column limiting its internal temperature, dropping the
local Eddington flux and increasing the gas pressure.Comment: 5 pages, 5 figures, accepted for publication in MNRAS Letter
Optically thick envelopes around ULXs powered by accreating neutron stars
Magnetized neutron stars power at least some ultra-luminous X-ray sources.
The accretion flow in these cases is interrupted at the magnetospheric radius
and then reaches the surface of a neutron star following magnetic field lines.
Accreting matter moving along magnetic field lines forms the accretion envelope
around the central object. We show that, in case of high mass accretion rates
the envelope becomes closed and optically
thick, which influences the dynamics of the accretion flow and the
observational manifestation of the neutron star hidden behind the envelope.
Particularly, the optically thick accretion envelope results in a multi-color
black-body spectrum originating from the magnetospheric surface. The spectrum
and photon energy flux vary with the viewing angle, which gives rise to
pulsations characterized by high pulsed fraction and typically smooth pulse
profiles. The reprocessing of radiation due to interaction with the envelope
leads to the disappearance of cyclotron scattering features from the spectrum.
We speculate that the super-orbital variability of ultra-luminous X-ray sources
powered by accreting neutron stars can be attributed to precession of the
neutron star due to interaction of magnetic dipole with the accretion disc.Comment: 8 pages, 6 figures, accepted for publication in MNRA
Coupling of radiation and magnetospheric accretion flow in ULX pulsars: radiation pressure and photon escape time
The accretion flow within the magnetospheric radius of bright X-ray pulsars
can form an optically thick envelope, concealing the central neutron star from
the distant observer. Most photons are emitted at the surface of a neutron star
and leave the system after multiple reflections by the accretion material
covering the magnetosphere. Reflections cause momentum to be transferred
between photons and the accretion flow, which contributes to the radiative
force and should thus influence the dynamics of accretion. We employ Monte
Carlo simulations and estimate the acceleration along magnetic field lines due
to the radiative force as well as the radiation pressure across magnetic field
lines. We demonstrate that the radiative acceleration can exceed gravitational
acceleration along the field lines, and similarly, radiation pressure can
exceed magnetic field pressure. Multiple reflections of X-ray photons back into
the envelope tend to amplify both radiative force along the field lines and
radiative pressure. We analyze the average photon escape time from the
magnetosphere of a star and show that its absolute value is weakly dependent on
the magnetic field strength of a star and roughly linearly dependent on the
mass accretion rate being at . At high mass accretion rates, the escape time can be longer than
free-fall time from the inner disc radius.Comment: accepted for publication MNRAS, 9 pages, 6 figure
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