The stellar mass in disc galaxies scales approximately with the fourth power of the rotation velocity, and the masses of the central black holes in galactic nuclei scale approximately with the fourth power of the bulge velocity dispersion. It is shown here that these relations can be accounted for if, in a forming galaxy with an isothermal mass distribution, gas with a column density above about 8M pc goes into stars, whereas gas with a column density above about 2 g cm (104 M pc) goes into a central black hole. The lower critical value is close to the column density of about 10M pc at which atomic gas becomes molecular, and the upper value agrees approximately with the column density of about 1 g cm at which the gas becomes optically thick to its cooling radiation. These results are plausible because molecule formation is evidently necessary for star formation, and because the onset of a high optical depth in a galactic nucleusmay suppress continuing star formation and favour the growth of a central black hole.
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机译:盘状星系中的恒星质量大约与旋转速度的四次方成比例,并且银河核中中心黑洞的质量与膨胀速度弥散的四次方量中成比例。此处显示,如果在等温质量分布的形成星系中,柱密度高于约8M pc的气体进入恒星,而柱密度高于约2 g cm(104 M, pc)进入中央黑洞。较低的临界值接近于原子气体变成分子的大约10M pc的柱密度,并且较高的值大约与大约1 g cm的柱密度一致,在大约1 g cm的气体中,气体对冷却辐射呈光学厚度。这些结果是合理的,因为分子形成显然是恒星形成所必需的,并且因为银河原子核中高光学深度的出现可能会抑制持续的恒星形成并有利于中心黑洞的生长。
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