Physical properties of embedded clusters in ATLASGAL clumps with HII regions

TL;DR

This study models the physical properties of embedded star clusters in ATLASGAL HII regions, highlighting the importance of accretion luminosity and star formation history in explaining observed bolometric luminosities.

Contribution

It introduces a synthetic modeling approach incorporating age spread, accretion, and star formation histories to better match observations of embedded clusters in HII regions.

Findings

Accretion luminosity significantly impacts low-mass HII-clumps' total luminosity.

Burst-like and time-varying star formation histories fit observational data better.

At least 20% of stars in embedded clusters are still accreting, affecting luminosity estimates.

Abstract

Using the optimal sampling model, we synthesized the embedded clusters of ATLASGAL clumps with HII regions (HII-clumps). The 0.1 Myr isochrone was used to estimate the bolometric luminosity of each star in an embedded cluster, we also added the accretion luminosity of each star in the embeded cluster. The total bolometric luminosity of synthetic embedded clusters can well fit the observed bolometric luminosity of HII-clumps. More realistically, we considered the age spread in the young star and protostar populations in embedded clusters of HII-clumps by modeling both constant and time-varying star formation histories (SFHs). According to the age distribution of the stellar population, we distributed the appropriate isochrones to each star, and sorted out the fraction of stellar objects that are still protostars (Class 0 and Class I phases) to properly add their accretion luminosities. Compared to a constant SFH, burst-like and time-dependent SFHs can better fit the observational data. We found that as long as 20\% of the stars within the embedded cluster are still accreting, the contribution of accretion luminosity will be significant to the total bolometric luminosity of low-mass HII-clumps with mass log$_{10}$(M$_{\rm cl}$/M$_{\odot}$) $<$ 2.8. Variations in the accretion rate, the SFE and the initial mass function (IMF) and more physical processes like the external heating from HII regions and the flaring from pre-main sequence (PMS) stars and protostars need to be investigated to further explain the excess luminosity of low-mass HII-clumps.