The Astronomical Journal (Jan 2025)
G321.93-0.01: A Rare Site of Multiple Hub-filament Systems with Evidence of Collision and Merging of Filaments
Abstract
Hub-filament systems (HFSs) are potential sites of massive star formation (MSF). To understand the role of filaments in MSF and the origin of HFSs, we conducted a multiscale and multiwavelength observational investigation of the molecular cloud G321.93–0.01. The ^13 CO( J = 2–1) data reveal multiple HFSs, namely, HFS-1, HFS-2, and a candidate HFS (C-HFS). HFS-1 and HFS-2 exhibit significant mass accretion rates ( ${\dot{M}}_{| | }$ > 10 ^−3 M _⊙ yr ^−1 ) to their hubs (i.e., Hub-1 and Hub-2, respectively). Hub-1 is comparatively massive, having higher ${\dot{M}}_{| | }$ than Hub-2, allowing to derive a relationship ${\dot{M}}_{| | }\propto {M}_{{\rm{hub}}}^{\beta }$ , with β ~ 1.28. Detection of three compact H ii regions within Hub-1 using MeerKAT 1.28 GHz radio continuum data and the presence of a clump (ATL-3), which meets Kauffmann and Pillai's criteria for MSF, confirm the massive star-forming activity in HFS-1. We find several low-mass Atacama Large Millimeter/submillimeter Array cores (1–9 M _⊙ ) inside ATL-3. The presence of a compact H ii region at the hub of C-HFS confirms that it is active in MSF. Therefore, HFS-1 and C-HFS are in relatively evolved stages of MSF, where massive stars have begun ionizing their surroundings. Conversely, despite a high ${\dot{M}}_{| | }$ , the nondetection of radio continuum emission toward Hub-2 suggests it is in the relatively early stages of MSF. Analysis of ^13 CO( J = 2–1) data reveals that the formation of HFS-1 was likely triggered by the collision of a filamentary cloud about 1 Myr ago. In contrast, the relative velocities (≳1 km s ^−1 ) among the filaments of HFS-2 and C-HFS indicate their formation through the merging of filaments.
Keywords
