A large-scale CO survey of the Rosette Molecular Cloud: assessing the effects of O stars on surrounding molecular gas

TL;DR

This large-scale CO survey of the Rosette Molecular Cloud reveals how O stars influence surrounding gas, showing expansion, heating, and star formation activity, with detailed analysis of clump dynamics and molecular flows.

Contribution

The study provides the first extensive CO J=3-2 survey of the Rosette Cloud, analyzing clump properties, gas dynamics, and star formation effects caused by O stars.

Findings

Most clumps show velocity gradients away from O stars.

Molecular ring exhibits expansion velocity of 30 km/s.

High-velocity flows correlate with young star clusters.

Abstract

We present a new large-scale survey of J=3-2 12CO emission covering 4.8 square degrees around the Rosette Nebula. Approximately 2000 compact clumps are identified, with a spatially-invariant power law mass distribution index of -1.8. Most of the inner clumps show velocity gradients of 1-3 km/s/pc, directed away from the exciting nebula. The gradients decrease with distance from the central O stars, and are consistent with a photoionised gas acceleration model, assuming clump lifetimes of a few 10^5 yrs. However, in one clear case, the observed near-constant velocity gradient is difficult to explain with simple models. Most blue-shifted but very few of the red-shifted clumps are associated with dark absorbing optical globules, confirming that the dominant molecular gas motion is expansion away from the central nebula and O stars. Many clumps also lie in a molecular ring, having an expansion velocity of 30 km/s, radius 11pc, and dynamical lifetime of ~1Myr. The J=3-2/1-0 12CO line ratios of the clumps decrease with distance from the O stars, implying a gradient in their surface temperatures; the results are consistent with a simple model of clump surface heating due to the central stars. Seven high-velocity molecular flows are found in the region, with a close correspondence between these flows and embedded young clusters. These outflows are sufficiently energetic to drive local gas turbulence within each cluster. We find 14 clear examples of association between embedded young stars seen at 24um and CO clumps; these are thought to be photoevaporating molecular envelopes. The CO clumps without evidence of embedded stars tend to have lower velocity gradients, and it is suggested that the presence of the young star may extend the lifespan of the photoevaporating envelope.