Dust Buried Compact Sources in the Dwarf Galaxy NGC 4449

TL;DR

This study identifies and characterizes young, dusty star clusters in NGC 4449, revealing their properties and suggesting that pre-supernova feedback may not always clear natal cocoons, challenging existing star formation models.

Contribution

It reports the discovery of compact, dusty star clusters with ages around 5-6 Myr in NGC 4449, highlighting potential limitations of current feedback models.

Findings

Clusters are heavily dust-enshrouded with A_V > 6 mag.

Clusters are extremely compact, about 1 pc in radius.

HII regions may be stalled, indicating incomplete feedback effects.

Abstract

Multi-wavelength images from the Hubble Space Telescope covering the wavelength range 0.27-1.6 $\mu$m show that the central area of the nearby dwarf galaxy NGC4449 contains several tens of compact sources that are emitting in the hydrogen recombination line Pa$\beta$ (1.2818 $\mu$m) but are only marginally detected in H$\alpha$ (0.6563 $\mu$m) and undetected at wavelengths $\lambda\le$0.55 $\mu$m. An analysis of the spectral energy distributions (SEDs) of these sources indicates that they are likely relatively young star clusters heavily attenuated by dust. The selection function used to identify the sources prevents meaningful statistical analyses of their age, mass, and dust extinction distributions. However, these cluster candidates have ages $\sim$5-6 Myr and A$_V>$6 mag, according to their SED fits, and are extremely compact, with typical deconvolved radii of 1 pc. The dusty clusters are located at the periphery of dark clouds within the galaxy and appear to be partially embedded. Density and pressure considerations indicate that the HII regions surrounding these clusters may be stalled, and that pre-supernova feedback has not been able to clear the clusters of their natal cocoons. These findings are in potential tension with existing models that regulate star formation with pre-supernova feedback, since pre-supernova feedback acts on short timescales, $\lesssim$4 Myr, for a standard Stellar Initial Mass function. The existence of a population of dusty star clusters with ages $>$4 Myr, if confirmed by future observations, paints a more complex picture for the role of stellar feedback in controlling star formation.