The core population and kinematics of a massive clump at early stages: an ALMA view

TL;DR

This study uses ALMA observations to analyze the properties and kinematics of prestellar cores in a high-mass star-forming clump, supporting a clump-fed accretion scenario with mostly low-mass, gravitationally bound cores.

Contribution

It provides detailed observational evidence of prestellar core properties and large-scale gas kinematics in a high-mass star-forming region, supporting the clump-fed accretion model.

Findings

Cores are mostly low-mass with transonic to mildly supersonic turbulence.

Identified four main velocity coherent structures associated with cores.

Estimated mass accretion rate of approximately 2 x 10^-4 solar masses per year.

Abstract

High-mass star formation theories make distinct predictions on the properties of the prestellar seeds of high-mass stars. Observations of the early stages of high-mass star formation can provide crucial constraints, but they are challenging and scarce. We investigate the properties of the prestellar core population embedded in the high-mass clump AGAL014.492-00.139, and we study the kinematics at the clump and the clump-to-core scales. We have analysed an extensive dataset acquired with the ALMA interferometer. Applying a dendrogram analysis to the Band o-$\rm H_2D^+$ data, we identified 22 cores. We have fitted their average spectra in local-thermodinamic-equilibrium conditions, and we analysed their continuum emission at $0.8 \, \rm mm$. The cores have transonic to mildly supersonic turbulence levels and appear mostly low-mass, with $M_\mathrm{core}< 30 \, \rm M_\odot$. Furthermore, we have analysed Band 3 observations of the $\rm N_2H^+$ (1-0) transition, which traces the large scale gas kinematics. Using a friend-of-friend algorithm, we identify four main velocity coherent structures, all of which are associated with prestellar and protostellar cores. One of them presents a filament-like structure, and our observations could be consistent with mass accretion towards one of the protostars. In this case, we estimate a mass accretion rate of $ \dot{M}_\mathrm{acc}\approx 2 \times 10^{-4} \rm \, M_\odot \, yr^{-1}$. Our results support a clump-fed accretion scenario in the targeted source. The cores in prestellar stage are essentially low-mass, and they appear subvirial and gravitationally bound, unless further support is available for instance due to magnetic fields.