Power distributions for self-gravitating astrophysical systems based on nonextensive Tsallis kinetics

The long-time development of self-gravitating gaseous astrophysical systems (in particular, the evolution of the protoplanet accretion disk) is mainly determined by relatively fast processes of the collision relaxation of particles. However, slower dynamical processes related to force (Newton or Cou...

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Bibliographic Details
Published in:Solar system research 2017-03, Vol.51 (2), p.127-144
Main Author: Kolesnichenko, A. V.
Format: Article
Language:English
Subjects:
Accretion
Accretion disks
Astronomy
Astrophysics
Astrophysics and Astroparticles
Astrophysics and Cosmology
Dynamical systems
Evolution
Gravitation
Gravitational waves
Kinetics
Mathematical analysis
Observations and Techniques
Parameters
Physics
Physics and Astronomy
Planetology
Power distribution
Protoplanets
Thermodynamics
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Summary:The long-time development of self-gravitating gaseous astrophysical systems (in particular, the evolution of the protoplanet accretion disk) is mainly determined by relatively fast processes of the collision relaxation of particles. However, slower dynamical processes related to force (Newton or Coulomb) interactions between particles should be included (as q -collisions) in the nonextensive kinetic theory as well. In the present paper, we propose a procedure to include the Newton self-gravity potential and the centrifugal potential in the near-equilibrium power-like q -distribution in the phase space, obtained (in the framework of nonextensive statistics) by means of the modified Boltzmann equation averaged with respect to an unnormalized distribution. We show that if the power distribution satisfies the stationary q -kinetic equation, then the said equation imposes clear restrictions on the character of the long-term force field and on the possible dependence of hydrodynamic parameters of the coordinates: it determines those parameters uniquely. We provide a thermodynamic stability criterion for the equilibrium of the nonextensive system. The results allow us to simulate the evolution of gaseous astrophysical systems (in particular, the gravitational stability of rotating protoplanet accretion disks) more adequately.
ISSN:0038-0946
1608-3423
DOI:10.1134/S0038094617020046