Probing fragmentation and velocity sub-structure in the massive NGC 6334 filament with ALMA

TL;DR

This study uses ALMA observations to analyze the fragmentation and velocity structure of the high-mass star-forming filament NGC 6334, revealing similarities with low-mass filaments and supporting the filament paradigm in high-mass star formation.

Contribution

It provides detailed insights into the density and velocity sub-structure of a high-mass filament, demonstrating similarities with low-mass filaments and supporting the universality of the filament paradigm.

Findings

Detected 26 cores and 5 velocity-coherent features in NGC 6334.

Core mass distribution peaks at ~10 solar masses.

Fragmentation scales are consistent with the Jeans length and filament width.

Abstract

Herschel surveys of Galactic clouds support a paradigm for low-mass star formation in which dense filaments play a crucial role. The detailed fragmentation properties of star-forming filaments remain poorly understood, however, and the validity of the filament paradigm in the high-mass regime is still unclear. To investigate the density/velocity structure of the filament in the high-mass star-forming region NGC6334, we conducted ALMA observations in the 3mm continuum and the N2H+(1-0) line at ~3arcsec resolution. The filament was detected in both tracers. We identified 26 cores at 3mm and 5 velocity-coherent fiber-like features in N2H+ within the filament. The typical length of, and velocity difference between, the fiber-like features of the NGC6334 filament are reminiscent of the properties for the fibers of the low-mass star-forming filament B211/B213. Only 2 or 3 of the 5 velocity-coherent features are well aligned with the filament and may represent genuine, fiber sub-structures. The core mass distribution has a peak at ~10Msun. They can be divided into 7 groups of cores, closely associated with ArTeMiS clumps. The projected separation between cores and the projected spacing between clumps are roughly consistent with the effective Jeans length in the filament and a physical scale of about 4 times the filament width, respectively, suggesting a bimodal filament fragmentation process. Despite being one order of magnitude denser and more massive than the B211/B213 filament, the NGC6334 filament has a similar density/velocity structure. The difference is that the cores in NGC6334 appear to be an order of magnitude denser and more massive than the cores in Taurus. This suggests that dense filaments may evolve and fragment in a similar manner in low- and high-mass star-forming regions, and that the filament paradigm may hold in the intermediate-mass (if not high-mass) star formation regime.