Super Hot Cores in NGC 253: Witnessing the formation and early evolution of Super Star Clusters

TL;DR

This study uses high-resolution ALMA imaging to identify and analyze Super Hot Cores in NGC 253, revealing their properties, evolutionary stages, and implications for star cluster formation.

Contribution

First detailed characterization of Super Hot Cores in NGC 253, linking their properties to the early stages of Super Star Cluster formation and evolution.

Findings

Identified 8 unresolved Super Hot Cores with high temperatures and densities.

Established evolutionary stages of SSCs from proto- to ZAMS-SSCs based on luminosity ratios.

Found an inside-out formation pattern of SSCs in NGC 253.

Abstract

Using $0.2^{\prime \prime}$ ($\sim3$ pc) ALMA images of vibrationally excited HC$_3$N emission (HC$_3$N$^*$) we reveal the presence of $8$ unresolved Super Hot Cores (SHCs) in the inner $160$ pc of NGC\,253. Our LTE and non-LTE modelling of the HC$_3$N$^*$ emission indicate that SHCs have dust temperatures of $200-375$ K, relatively high H$_2$ densities of $1-6\times 10^{6}$ cm$^{-3}$ and high IR luminosities of $0.1-1\times 10^8$ L$_\odot$. As expected from their short lived phase ($\sim 10^4$ yr), all SHCs are associated with young Super Star Clusters (SSCs). We use the ratio of luminosities form the SHCs (protostar phase) and from the free-free emission (ZAMS star phase), to establish the evolutionary stage of the SSCs. The youngest SSCs, with the larges ratios, have ages of a few $10^4$ yr (proto-SSCs) and the more evolved SSCs are likely between $10^5$ and $10^6$ yr (ZAMS-SSCs). The different evolutionary stages of the SSCs are also supported by the radiative feedback from the UV radiation as traced by the HNCO/CS ratio, with this ratio being systematically higher in the young proto-SSCs than in the older ZAMS-SSCs. We also estimate the SFR and the SFE of the SSCs. The trend found in the estimated SFE ($\sim40\%$ for proto-SSCs and $>85\%$ for ZAMS-SSCs) and in the gas mass reservoir available for star formation, one order of magnitude higher for proto-SSCs, suggests that star formation is still going on in proto-SSCs. We also find that the most evolved SSCs are located, in projection, closer to the center of the galaxy than the younger proto-SSCs, indicating an inside-out SSC formation scenario.