A Maximum Stellar Surface Density in Dense Stellar Systems

TL;DR

This paper shows that dense stellar systems, regardless of their size or type, share a universal maximum surface density likely regulated by feedback from massive stars, indicating a fundamental physical limit in star formation.

Contribution

It identifies a universal maximum stellar surface density across diverse systems and proposes stellar feedback as the key regulatory mechanism, challenging existing galaxy formation models.

Findings

Maximum stellar surface density is ~10^11 M_sun/kpc^2 across systems.

The density limit is independent of total mass and physical scale.

Stellar feedback likely sets this universal density limit.

Abstract

We compile observations of the surface mass density profiles of dense stellar systems, including globular clusters in the Milky Way and nearby galaxies, massive star clusters in nearby starbursts, nuclear star clusters in dwarf spheroidals and late-type disks, ultra-compact dwarfs, and galaxy spheroids spanning the range from low-mass cusp bulges and ellipticals to massive core ellipticals. We show that in all cases the maximum stellar surface density attained in the central regions of these systems is similar, Sigma_max ~ 10^11 M_sun/kpc^2 (~20 g/cm^2), despite the fact that the systems span 7 orders of magnitude in total stellar mass M_star, 5 in effective radius R_e, and have a wide range in effective surface density M_star/R_e^2. The surface density limit is reached on a wide variety of physical scales in different systems and is thus not a limit on three-dimensional stellar density. Given the very different formation mechanisms involved in these different classes of objects, we argue that a single piece of physics likely determines Sigma_max. The radiation fields and winds produced by massive stars can have a significant influence on the formation of both star clusters and galaxies, while neither supernovae nor black hole accretion are important in star cluster formation. We thus conclude that feedback from massive stars likely accounts for the observed Sigma_max, plausibly because star formation reaches an Eddington-like flux that regulates the growth of these diverse systems. This suggests that current models of galaxy formation, which focus on feedback from supernovae and active galactic nuclei, are missing a crucial ingredient.