Early stages of cluster formation: fragmentation of massive dense cores down to ~1000 AU

TL;DR

This study investigates how massive dense cores fragment into smaller structures, revealing that magnetic fields and turbulence influence the fragmentation process, with some cores showing no fragmentation and others splitting into multiple sources.

Contribution

It provides high-resolution observations of core fragmentation down to 1000 AU and compares these with simulations to assess magnetic and turbulent effects.

Findings

Approximately 30% of cores show no fragmentation.

About 50% of cores fragment into around 4 sources.

Fragmentation correlates with the magnetic field and turbulence balance.

Abstract

In order to study the fragmentation of massive dense cores, which constitute the cluster cradles, we observed with the PdBI in the most extended configuration the continuum at 1.3 mm and the CO(2-1) emission of four massive cores. We detect dust condensations down to ~0.3 Msun and separate millimeter sources down to 0.4" or ~1000 AU, comparable to the sensitivities and separations reached in optical/infrared studies of clusters. The CO(2-1) high angular resolution images reveal high-velocity knots usually aligned with previously known outflow directions. This, in combination with additional cores from the literature observed at similar mass sensitivity and spatial resolution, allowed us to build a sample of 18 protoclusters with luminosities spanning 3 orders of magnitude. Among the 18 regions, ~30% show no signs of fragmentation, while 50% split up into ~4 millimeter sources. We compiled a list of properties for the 18 massive dense cores, such as bolometric luminosity, total mass, and mean density, and found no correlation of any of these parameters with the fragmentation level. In order to investigate the combined effects of magnetic field, radiative feedback and turbulence in the fragmentation process, we compared our observations to radiation magneto-hydrodynamic simulations, and found that the low-fragmented regions are well reproduced in the magnetized core case, while the highly-fragmented regions are consistent with cores where turbulence dominates over the magnetic field. Overall, our study suggests that the fragmentation in massive dense cores could be determined by the initial magnetic field/turbulence balance in each particular core.