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Hot Radiative Accretion onto a Spinning Neutron Star | Mikhail V. Medvedev
; | Date: |
2 Jul 2004 | Subject: | astro-ph | Affiliation: | University of Kansas | Abstract: | (Abridged) A new type of self-similar hot viscous radiative accretion flow onto a rapidly spinning neutron star has recently been discovered. This ``hot brake’’ flow forms in the two-temperature zone (close to a central object), but at a sufficiently low accretion rate and a high spin it may extend in the radial direction beyond ~300 Schwarzchild radii into a one-temperature zone. When the spin of the star is small enough, the flow transforms smoothly to an advection-dominated accretion flow. All gas parameters (density, angular velocity, temperature, luminosity, angular momentum flux) except for the radial velocity are independent of the mass accretion rate. The radiative efficiency may be arbitrarily large as M-dot -> 0. The gas angular momentum is transported outward under most conditions, hence the central star is nearly always spun-down. The flow is convectively stable. We also find that themal conduction in the flow is strong enough to make the flow thermally stable. The very fact that the density, temperature and angular velocity of the gas at any radius in the hot brake flow are completely independent of the outer and inner (except for the star spin) boundary conditions implies that the flow cannot be smoothly matched to a general external medium as well as to general conditions on the star surface. We demonstrate that there are two extra self-similar solutions: one bridges the gap between the original solution and the external medium, and another represents a boundary layer between the bulk of the flow and the star surface, in which the gas temperature rapidly drops while the density builds up. Finally, we briefly discuss that a hot brake flow may form around other rapidly spinning compact objects: white dwarfs and black holes. | Source: | arXiv, astro-ph/0407062 | Services: | Forum | Review | PDF | Favorites |
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