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A class of self-gravitating accretion disks

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arxiv astro-ph/9908095 v1 pith:XO6DFWIT submitted 1999-08-09 astro-ph

A class of self-gravitating accretion disks

classification astro-ph
keywords accretiondisksdiskself-regulatedclassextensionself-gravitatingabsence
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We consider a class of steady-state self-gravitating accretion disks for which efficient cooling mechanisms are assumed to operate so that the disk is self-regulated at a condition of approximate marginal Jeans stability. In an earlier paper, this scenario had been shown to lead naturally, in the absence of a central point mass, to a self-similar solution characterized by a flat rotation curve. In this article we investigate the entire parameter space available for such self-regulated accretion disks and provide two non-trivial extensions of the model. The first extension is that of a bimodal disk, obtained by partially relaxing the self-regulation constraint, so that full matching with an inner "standard" Keplerian accretion disk takes place. The second extension is the construction of self-regulated accretion disks embedded in a diffuse spherical "halo". The analysis is further strengthened by a careful discussion of the vertical structure of the disk, in such a way that the transition from self-gravity dominated to non-gravitating disks is covered uniformly.

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