CO-0.30-0.07: A Peculiar Molecular Clump with an Extremely Broad Velocity Width

TL;DR

This study investigates the peculiar molecular cloud CO-0.30-0.07 in the Milky Way's central region, revealing its broad velocity features, collision dynamics, and shock-induced clump formation, suggesting early star formation activity.

Contribution

The paper provides high-resolution interferometric maps and analysis of the cloud's velocity structure, proposing a collision model and identifying shock-formed dense clumps with star formation potential.

Findings

Broad velocity emissions confined to two parallel ridges.

Distinct velocity components likely due to cloud collision.

Detection of dense, shock-compressed clumps with star-forming features.

Abstract

The high velocity dispersion compact cloud CO-0.30-0.07 is a peculiar molecular clump discovered in the central moleculr zone of the Milky Way, which is characterized by its extremely broad velocity emissions ($\sim 145\ \rm{km s^{-1}}$) despite the absence of internal energy sources. We present new interferometric maps of the cloud in multiple molecular lines in frequency ranges of 265--269 GHz and 276--280 GHz obtained using the Sumbmillimeter Array, along with the single-dish images previously obtained with the ASTE 10-m telescope. The data show that the characteristic broad velocity emissions are predominantly confined in two parallel ridges running through the cloud center. The central ridges are tightly anti-correlated with each other in both space and velocity, thereby sharply dividing the entire cloud into two distinct velocity components (+15 km s$^{-1}$ and +55 km s$^{-1}$). This morphology is consistent with a model in which the two velocity components collide with a relative velocity of 40 $\mathrm{km s^{-1}}$ at the interface defined by the central ridges, although an alternative explanation with a highly inclined expanding-ring model is yet to be fully invalidated. We have also unexpectedly detected several compact clumps ($\lesssim 0.1\ $pc in radius) likely formed by shock compression. The clumps have several features in common with typical star-forming clouds: high densities ($10^{6.5-7.5}\ \mathrm{cm^{-3}}$), rich abundances of hot-core-type molecular species, and relatively narrow velocity widths apparently decoupled from the furious turbulence dominating the cloud. The cloud CO-0.30-0.07 is possibly at an early phase of star formation activity triggered by the shock impact.