Astronomy and Astrophysics – Astrophysics
Scientific paper
1996-06-30
Astronomy and Astrophysics
Astrophysics
includes 10 postscript figs, uses psfig.sty (not included); submitted to New Astronomy
Scientific paper
10.1016/S1384-1076(96)00018-8
The collapse time for a cluster of equal-mass stars is usually stated to be either 330 central relaxation times ($\trc$) or 12--19 half-mass relaxation times ($\trh$). But the first of these times applies only to the late stages of core collapse, and the second only to low-concentration clusters. To clarify how the time depends on the mass distribution, the Fokker-Planck equation is solved for the evolution of a variety of isotropic cluster models, including King models, models with power-law density cusps of $\rho\sim r^{-\gamma}$, and models with nuclei. High-concentration King models collapse faster than low-concentration models if the time is measured in units of $\trh$, but slower if it is measured in units of $\trc$. Models with cusps evolve faster than King models, but not all of them collapse: those with $0<\gamma<2$ expand because they start with a temperature inversion. Models with nuclei collapse or expand as the nuclei would in isolation if their central relaxation times are short; otherwise their evolution is more complicated. Suggestions are made for how the results can be applied to globular clusters, galaxies, and hypothetical clusters of dark stars in the centers of galaxies.
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