Abstract
In accreting neutron star binaries, matter is channelled by the magnetic fields from the accretion disc to the poles of neutron stars forming an accretion mound. We model such mounds by numerically solving the Grad-Shafranov equation for axisymmetric static MHD equilibria. From our solutions we infer local distortion of field lines due to the weight of accreted matter. Variation in mass loading at the accretion disc will alter the shape of the accretion mound which will also affect the local field distortion. From simulations of cyclotron resonance scattering features from HMXBs, we conclude that local field distortion will greatly affect the shape and nature of the CRSF. From phase resolved spectral analysis one can infer the local field structure and hence the nature of mass loading of field lines at the accretion disc. We also study the stability of such mounds by performing MHD simulations using the PLUTO MHD code. We find that pressure and gravity driven instabilities depend on the total mass accreted and the nature of mass loading of the field lines.
Highlights
In accreting neutron stars with an extended magnetosphere matter proceeds along the fields towards the magnetic poles
From simulations of cyclotron resonance scattering features from HMXBs, we conclude that local field distortion will greatly affect the shape and nature of the CRSF
We study the stability of such mounds by performing MHD simulations using the PLUTO MHD code
Summary
In accreting neutron stars with an extended magnetosphere matter proceeds along the fields towards the magnetic poles. The magnetic structure inside the accretion column and its local dynamics will have important concequences on the observed X-ray emission from such system. For neutron stars with high surface magnetic field (∼ 1012), the Xray emission show cyclotron scattering features which depend on the local magnetic field, and can be used as a tool to probe the structure of the accretion column. We discuss the effect of the field distortion and local dynamics on the emitted CRSF spectra
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