The distribution of stellar mass in the low-redshift Universe

TL;DR

This study uses SDSS data to analyze the distribution and clustering of stellar mass in low-redshift galaxies, revealing key statistical properties and their implications for galaxy formation models and cosmology.

Contribution

It provides a comprehensive measurement of stellar mass distribution, clustering, and bias, and compares these with theoretical models to inform cosmological parameters and dark energy tests.

Findings

Stellar mass function well fit by Schechter function with specific parameters.

Only 3.5% of baryons are in stars in the low-redshift universe.

Stellar mass autocorrelation follows a power-law over a wide scale range.

Abstract

We use a complete and uniform sample of almost half a million galaxies from the Sloan Digital Sky Survey to characterise the distribution of stellar mass in the low-redshift Universe. Galaxy abundances are well determined over almost four orders of magnitude in stellar mass, and are reasonably but not perfectly fit by a Schechter function with characteristic stellar mass m* = 6.7 x 10^10 M_sun and with faint-end slope \alpha = -1.155. For a standard cosmology and a standard stellar Initial Mass Function, only 3.5% of the baryons in the low-redshift Universe are locked up in stars. The projected autocorrelation function of stellar mass is robustly and precisely determined for r_p < 30 Mpc/h. Over the range 10 kpc/kpc < r_p < 10 Mpc/h it is extremely well represented by a power law. The corresponding three-dimensional autocorrelation function is \xi*(r) = (r/6.1 Mpc/h)^{-1.84}. Relative to the dark matter, the bias of the stellar mass distribution is approximately constant on large scales, but varies by a factor of five for r_p < 1 Mpc/h. This behaviour is approximately but not perfectly reproduced by current models for galaxy formation in the concordance LCDM cosmology. Detailed comparison suggests that a fluctuation amplitude \sigma_8 ~ 0.8 is preferred to the somewhat larger value adopted in the Millennium Simulation models with which we compare our data. This comparison also suggests that observations of stellar mass autocorrelations as a function of redshift might provide a powerful test for the nature of Dark Energy.