The distribution of local star formation activity as a function of galaxy stellar mass, environment and morphology

TL;DR

This study provides a comprehensive analysis of how local star formation activity depends on galaxy stellar mass, environment, and morphology, revealing that most star formation occurs in spiral galaxies in the field with intermediate stellar masses.

Contribution

It offers the first detailed inventory of local star formation as a function of mass, environment, and morphology using SDSS data, serving as a baseline for understanding cosmic star formation evolution.

Findings

65% of star formation occurs in spiral galaxies in the field

Star formation in ellipticals is significant only at higher masses

Field galaxies host the majority (21:3:1) of star formation compared to groups and clusters

Abstract

We present a detailed inventory of star formation in the local Universe, dissecting the cosmic star formation budget as a function of key variables that influence the star formation rate (SFR) of galaxies: stellar mass, local environment and morphology. We use a large homogeneous dataset from the SDSS to first study how the star-formation budget in galaxies with stellar masses greater than $\log (\textrm{M}_{*}/\textrm{M}_{\odot}) = 10$ splits as a function of each parameter separately. We then explore how the budget behaves as a simultaneous function of these three parameters. We show that the bulk of the star formation at $z<0.075$ ($\sim$65 per cent) takes place in spiral galaxies, that reside in the field, and have stellar masses between $10 < \log (\textrm{M}_{*}/\textrm{M}_{\odot}) < 10.9$. The ratio of the cosmic star formation budget hosted by galaxies in the field, groups and clusters is 21:3:1. Morphological ellipticals are minority contributors to local star formation. They make a measurable contribution to the star formation budget only at intermediate to high stellar masses, $10.3< \log (\textrm{M}_{*}/\textrm{M}_{\odot}) < 11.2 $ (where they begin to dominate by number), and typically in the field, where they contribute up to $\sim$13 per cent of the total star-formation budget. This inventory of local star formation serves as a $z\sim0$ baseline which, when combined with similar work at high redshift, will enable us to understand the changes in SFR that have occurred over cosmic time and offers a strong constraint on models of galaxy formation.