Low-Metallicity Star Formation Survey in Sh2-284 (LZ-STAR). II. The inital mass function

TL;DR

This study investigates the initial mass function (IMF) in a low-metallicity star-forming region using JWST data, finding the IMF peak shifts to lower masses compared to solar-metallicity environments, indicating metallicity influences star formation.

Contribution

First measurement of the IMF in a 1/3 solar metallicity environment using JWST, revealing a lower IMF peak mass and potential metallicity dependence.

Findings

IMF peak at 0.16 Msun in low-metallicity environment

IMF peak shifts to lower masses with decreasing metallicity

Results are sensitive to assumed stellar age

Abstract

To fully understand the star formation process, we are compelled to study it in a variety of environments. Of particular interest are how star formation and the resulting initial mass function (IMF) vary as a function of metallicity. We have observed an embedded young cluster in Sh2-284 (hereafter S284), the HII region associated with the open cluster Dolidze 25 using JWST/NIRCam with the aim to study star formation in a metal-poor, i.e., about 1/3 of solar, environment. In particular, we aim to measure the peak of the IMF. Using JWST NIRCam photometry, we identified the embedded cluster S284-EC1 and resolved its low-mass content. By comparison with pre-main sequence evolutionary tracks we determine the mass and extinction for the individual cluster members. Extinction limited samples are created based on the distribution of extinction and the completeness of the data. For the region with a completeness of 50% or higher, we have fitted a log-normal distribution to the IMF. Adopting a fiducial age of 1 Myr of the members, the peak of the IMF is found to be at mc = 0.16+-0.02Msun, which is significantly smaller than the peak mass measured in local young clusters, such as mc = 0.26+0.11-0.07 Msun in the Orion Nebula Cluster (Gennaro & Robberto 2020), or the local Galactic disk value of mc = 0.25 Msun (Chabrier 2005). We have found evidence for IMF variation as a function of metallicity, i.e., the peak of the IMF shifts to lower masses as one goes from solar to 1/3 solar metallicity. However, we caution that the result is sensitive to the assumed age of the stellar population, i.e., with peak mass rising if an age older than 1 Myr is adopted. This study further motivates the need for expanded samples of low-metallicity regions and their content to enable more comprehensive measures of the IMF in such environments.