Massive stars reveal variations of the stellar initial mass function in the Milky Way stellar clusters

TL;DR

This study examines the variability of the stellar initial mass function (IMF) in Milky Way clusters, proposing a probabilistic model that accounts for observed O star distributions and challenges the idea of a universal IMF.

Contribution

It introduces a new probabilistic approach to model the IMF parameters as Gaussian distributions, based on high-mass star observations in Galactic clusters.

Findings

Broad IMF parameter distributions are necessary to match observed O star fractions.

No evidence supports a cluster mass-maximum stellar mass relation.

Proposed Gaussian distributions for IMF parameters with specific means and dispersions.

Abstract

We investigate whether the stellar initial mass function (IMF) is universal, or whether it varies significantly among young stellar clusters in the Milky Way. We propose a method to uncover the range of variation of the parameters that describe the shape of the IMF for the population of young Galactic clusters. These parameters are the slopes in the low and high stellar mass regimes, $\gamma$ and $\Gamma$, respectively, and the characteristic mass, $M_{ch}$. The method relies exclusively on the high mass content of the clusters, but is able to yield information on the distributions of parameters that describe the IMF over the entire stellar mass range. This is achieved by comparing the fractions of single and lonely massive O stars in a recent catalog of the Milky Way clusters with a library of simulated clusters built with various distribution functions of the IMF parameters. The synthetic clusters are corrected for the effects of the binary population, stellar evolution, sample incompleteness, and ejected O stars. Our findings indicate that broad distributions of the IMF parameters are required in order to reproduce the fractions of single and lonely O stars in Galactic clusters. They also do not lend support to the existence of a cluster mass-maximum stellar mass relation. We propose a probabilistic formulation of the IMF whereby the parameters of the IMF are described by Gaussian distribution functions centered around $\gamma=0.91$, $\Gamma=1.37$, and $M_{ch}=0.41$ M$_{\odot}$, and with dispersions of $\sigma_{\gamma}=0.25$, $\sigma_{\Gamma}=0.60$, and $\sigma_{M_{ch}}=0.27$ M$_{\odot}$ around these values.