Fragmentation of Molecular Clumps and Formation of Protocluster

TL;DR

This study uses ALMA observations to explore the early fragmentation and protostar formation in a massive molecular cloud, revealing hierarchical core development and suggesting low-mass stars form later in cluster evolution.

Contribution

First detailed ALMA analysis of core fragmentation and chemical evolution in a protocluster within a filamentary IRDC, highlighting sequential star formation.

Findings

Detected five dusty cores with further fragmentation.

Identified chemically evolved cores with active outflows.

Observed velocity gradients indicating accretion flows.

Abstract

Sufficiently massive clumps of molecular gas collapse under self-gravity and fragment to spawn a cluster of stars that have a range of masses. We investigate observationally the early stages of formation of a stellar cluster in a massive filamentary infrared dark cloud, G28.34+0.06 P1, in the 1.3mm continuum and spectral line emission using the ALMA. Sensitive continuum data reveal further fragmentation in five dusty cores at a resolution of several 10^3 AU. Spectral line emission from C18O, CH3OH, 13CS, H2CO and N2D+ are detected for the first time toward these dense cores. We found that three cores are chemically more evolved as compared with the other two; interestingly though, all of them are associated with collimated outflows as suggested by evidence from the CO, SiO, CH3OH, H2CO and SO emissions. The parsec-scale kinematics in NH3 exhibit velocity gradients along the filament, consistent with accretion flows toward the clumps and cores. The moderate luminosity and the chemical signatures indicate that the five cores harbor low- to intermediate-mass protostars that likely become massive ones at the end of the accretion. Despite the fact that the mass limit reached by the 1\sigma dust continuum sensitivity is 30 times lower than the thermal Jeans mass, there is a lack of a distributed low-mass protostellar population in the clump. Our observations indicate that in a protocluster, low-mass stars form at a later stage after the birth of more massive protostars.