Parsec-scale SiO Emission in an Infrared Dark Cloud

TL;DR

This study maps SiO emission in an infrared dark cloud, revealing widespread shock-related activity likely linked to cloud formation and star formation processes, with distinct compact and extended SiO components.

Contribution

First high-sensitivity, large-scale SiO maps of an IRDC showing two distinct emission components and their association with star formation and cloud dynamics.

Findings

Widespread SiO emission along the IRDC with compact and extended components.

Broad SiO lines associated with high-mass protostellar outflows.

Narrow SiO lines suggest large-scale shocks or processed gas from cloud formation.

Abstract

We present high-sensitivity 2'x4' maps of the J=2-1 rotational lines of SiO, CO, 13CO and C18O, observed toward the filamentary Infrared Dark Cloud (IRDC) G035.39-00.33. Single-pointing spectra of the SiO J=2-1 and J=3-2 lines toward several regions in the filament, are also reported. The SiO images reveal that SiO is widespread along the IRDC (size >2 pc), showing two different components: one bright and compact arising from three condensations (N, E and S), and the other weak and extended along the filament. While the first component shows broad lines (linewidths of ~4-7 kms-1) in both SiO J=2-1 and SiO J=3-2, the second one is only detected in SiO J=2-1 and has narrow lines (~0.8 kms-1). The maps of CO and its isotopologues show that low-density filaments are intersecting the IRDC and appear to merge toward the densest portion of the cloud. This resembles the molecular structures predicted by flow-driven, shock-induced and magnetically-regulated cloud formation models. As in outflows associated with low-mass star formation, the excitation temperatures and fractional abundances of SiO toward N, E and S, increase with velocity from ~6 to 40 K, and from ~1E-10 to >1E-8 respectively, over a velocity range of ~7 kms-1. Since 8 micron sources, 24 micron sources and/or extended 4.5 micron emission are detected in N, E and S, broad SiO is likely produced in outflows associated with high-mass protostars. The excitation temperatures and fractional abundances of the narrow SiO lines, however, are very low (~9 K and ~1E-11, respectively), and consistent with the processing of interstellar grains by the passage of a shock with vs~12 kms-1. This emission could be generated i) by a large-scale shock, perhaps remnant of the IRDC formation process; ii) by decelerated or recently processed gas in large-scale outflows driven by 8 micron and 24 micron sources; or iii) by an undetected and widespread population of lower mass protostars. High-angular resolution observations are needed to disentangle between these three scenarios.