Magnetospheric Flows in X-ray Pulsars I: instability at super-Eddington regime of accretion
Magnetospheric Flows in X-ray Pulsars I: instability at super-Eddington regime of accretion
Within the magnetospheric radius, the geometry of accretion flow in X-ray pulsars is shaped by a strong magnetic field of a neutron star. Starting at the magnetospheric radius, accretion flow follows field lines and reaches the stellar surface in small regions located close to the magnetic poles of a star. At low mass accretion rates, the dynamic of the flow is determined by gravitational attraction and rotation of the magnetosphere due to the centrifugal force. At the luminosity range close to the Eddington limit and above it, the flow is additionally affected by the radiative force. We construct a model simulating accretion flow dynamics over the magnetosphere, assuming that the flow strictly follows field lines and is affected by gravity, radiative and centrifugal forces only. The magnetic field of a NS is taken to be dominated by the dipole component of arbitrary inclination with respect to the accretion disc plane. We show that accretion flow becomes unstable at high mass accretion rates and tends to fluctuate quasi-periodically with a typical period comparable to the free-fall time from the inner disc radius. The inclination of a magnetic dipole with respect to the disc plane and strong anisotropy of X-ray radiation stabilise the mass accretion rate at the poles of a star, but the surface density of material covering the magnetosphere fluctuates even in this case.
astro-ph.HE, astro-ph.SR
Mushtukov, A.A.
2ae32e71-4da3-485c-bae3-46376db70660
Ingram, A.
de12bdc3-2efb-461b-9755-29453ac8d065
Suleimanov, V.F.
e0f5fb67-c38a-42fa-bf12-6dcaab11de75
DiLullo, N.
2f366270-f0fc-4a89-bca9-9c489039b130
Middleton, M.
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Tsygankov, S.S.
057cc7f1-1bb8-463f-9c47-58f6ffda97b9
Klis, M. van der
d3635ef2-91fc-4d3a-b453-ac2861a9edb3
Zwart, S. Portegies
7b73daa1-fa7c-4346-9a26-fad66701732d
Mushtukov, A.A.
2ae32e71-4da3-485c-bae3-46376db70660
Ingram, A.
de12bdc3-2efb-461b-9755-29453ac8d065
Suleimanov, V.F.
e0f5fb67-c38a-42fa-bf12-6dcaab11de75
DiLullo, N.
2f366270-f0fc-4a89-bca9-9c489039b130
Middleton, M.
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Tsygankov, S.S.
057cc7f1-1bb8-463f-9c47-58f6ffda97b9
Klis, M. van der
d3635ef2-91fc-4d3a-b453-ac2861a9edb3
Zwart, S. Portegies
7b73daa1-fa7c-4346-9a26-fad66701732d
[Unknown type: UNSPECIFIED]
Abstract
Within the magnetospheric radius, the geometry of accretion flow in X-ray pulsars is shaped by a strong magnetic field of a neutron star. Starting at the magnetospheric radius, accretion flow follows field lines and reaches the stellar surface in small regions located close to the magnetic poles of a star. At low mass accretion rates, the dynamic of the flow is determined by gravitational attraction and rotation of the magnetosphere due to the centrifugal force. At the luminosity range close to the Eddington limit and above it, the flow is additionally affected by the radiative force. We construct a model simulating accretion flow dynamics over the magnetosphere, assuming that the flow strictly follows field lines and is affected by gravity, radiative and centrifugal forces only. The magnetic field of a NS is taken to be dominated by the dipole component of arbitrary inclination with respect to the accretion disc plane. We show that accretion flow becomes unstable at high mass accretion rates and tends to fluctuate quasi-periodically with a typical period comparable to the free-fall time from the inner disc radius. The inclination of a magnetic dipole with respect to the disc plane and strong anisotropy of X-ray radiation stabilise the mass accretion rate at the poles of a star, but the surface density of material covering the magnetosphere fluctuates even in this case.
Text
2402.12965v1
- Author's Original
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e-pub ahead of print date: 20 February 2024
Additional Information:
14 pages, 13 figures, submitted to MNRAS
Keywords:
astro-ph.HE, astro-ph.SR
Identifiers
Local EPrints ID: 489021
URI: http://eprints.soton.ac.uk/id/eprint/489021
PURE UUID: eeda2031-c7dc-4132-b9ba-65a82241927d
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Date deposited: 11 Apr 2024 16:32
Last modified: 11 Apr 2024 16:32
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Contributors
Author:
A.A. Mushtukov
Author:
A. Ingram
Author:
V.F. Suleimanov
Author:
N. DiLullo
Author:
S.S. Tsygankov
Author:
M. van der Klis
Author:
S. Portegies Zwart
Corporate Author: et al.
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