Star formation in the Local Group as seen by low-mass stars

TL;DR

This study uses HST data to analyze pre-main sequence stars across different environments, revealing how mass, age, and metallicity influence accretion rates and star formation processes.

Contribution

Introduces a novel method combining broad-band and narrow-band photometry to characterize over 3000 PMS stars across multiple galaxies, expanding the sample size and diversity.

Findings

Mass accretion rate scales with age, stellar mass, and inversely with metallicity.

Higher accretion rates observed in the Magellanic Clouds compared to the Milky Way.

Provides the largest homogeneous dataset of PMS stars with physical parameters.

Abstract

We have undertaken a systematic study of pre-main sequence (PMS) stars spanning a wide range of masses (0.5 - 4 Msolar), metallicities (0.1 - 1 Zsolar) and ages (0.5 - 30 Myr). We have used the Hubble Space Telescope (HST) to identify and characterise a large sample of PMS objects in several star-forming regions in the Magellanic Clouds, namely 30 Dor and the SN 1987A field in the LMC, and NGC 346 and NGC 602 in the SMC, and have compared them to PMS stars in similar regions in the Milky Way, such as NGC 3603 and Trumpler 14, which we studied with the HST and Very Large Telescope (VLT). We have developed a novel method that combines broad-band (V, I) photometry with narrow-band Halpha imaging to determine the physical parameters (temperature, luminosity, age, mass and mass accretion rate) of more than 3000 bona-fide PMS stars still undergoing active mass accretion. This is presently the largest and most homogeneous sample of PMS objects with known physical properties and includes not only very young objects, but also PMS stars older than 10 - 20 Myr that are approaching the main sequence (MS). We find that the mass accretion rate scales roughly with the square root of the age, with the mass of the star to the power of 1.5, and with the inverse of the cube root of the metallicity. The mass accretion rates for stars of the same mass and age are thus systematically higher in the Magellanic Clouds than in the Milky Way. These results are bound to have important implications for, and constraints on our understanding of the star formation process.