Assessing molecular line diagnostics of triggered star formation using synthetic observations

TL;DR

This study uses synthetic molecular line observations to identify signatures of triggered star formation in bright rimmed clouds, revealing how line profile asymmetries and viewing angles inform about cloud dynamics and star formation processes.

Contribution

It provides new insights into interpreting molecular line profiles in BRCs, linking asymmetries and velocity separations to triggered star formation and cloud motion, based on radiation-hydrodynamic models.

Findings

Line profile asymmetries depend on viewing angle and shell density.

Most BRC line profiles are symmetric, with asymmetries caused by shell-cloud interactions.

Blue line components can indicate the shell moving towards the observer.

Abstract

We investigate observational signatures of triggered star formation in bright rimmed clouds (BRCs) by using molecular line transfer calculations based on radiation-hydrodynamic radiatively-driven-implosion models. We find that for BRCs the separation in velocity between the line profile peak of an optically thick and an optically thin line is determined by both the observer viewing angle and the density of the shell driving into the cloud. In agreement with observations, we find that most BRC line profiles are symmetric and that asymmetries can be either red or blue, in contrast to the blue-dominance expected for a collapsing cloud. Asymmetries in the line profiles arise when an optically thick line is dominated by the shell and an optically thin line is dominated by the cloud interior to the shell. The asymmetries are red or blue depending on whether the shell is moving towards or away from the observer respectively. Using the known motions of the molecular gas in our models we rule out the envelope expansion with core collapse mechanism as the cause of the lack of blue-asymmetry in our simulated observations. We show that the absence of a strong photon dominated region (PDR) around a BRC may not rule out the presence of triggered star formation: if the BRC line profile has a strong blue component then the shell is expected to be driving towards the observer, suggesting that the cloud is being viewed from behind and the PDR is obstructed. This could explain why BRCs such as SFO 80, 81 and 86 have a blue secondary peak and only a weak PDR inferred at 8 microns. Finally we also test the use of 12CO, 13CO and C18O as diagnostics of cloud mass, temperature and column density. We find that the inferred conditions are in reasonable agreement with those from the models.