Chemical stratification in the Orion Bar: JCMT Spectral Legacy Survey observations

TL;DR

This study maps molecular emissions in the Orion Bar PDR, revealing chemical layering and comparing observations with models, highlighting the need for more complex chemistry in models.

Contribution

First detailed spectral mapping of multiple molecules in the Orion Bar, demonstrating chemical stratification and testing PDR models against observations.

Findings

Clear chemical stratification observed in molecular emissions.

Discrepancies between model predictions and observed abundances.

Indication that grain surface chemistry should be included in models.

Abstract

Photon-dominated regions (PDRs) are expected to show a layered structure in molecular abundances and emerging line emission, which is sensitive to the physical structure of the region as well as the UV radiation illuminating it. We aim to study this layering in the Orion Bar, a prototypical nearby PDR with a favorable edge-on geometry. We present new maps of 2 by 2 arcminute fields at 14-23 arcsecond resolution toward the Orion Bar in the SO 8_8-9_9, H2CO 5_(1,5)-4_(1,4), 13CO 3-2, C2H 4_(9/2)-3_(7/2) and 4_(7/2)-3_(5/2), C18O 2-1 and HCN 3-2 transitions. The data reveal a clear chemical stratification pattern. The C2H emission peaks close to the ionization front, followed by H2CO and SO, while C18O, HCN and 13CO peak deeper into the cloud. A simple PDR model reproduces the observed stratification, although the SO emission is predicted to peak much deeper into the cloud than observed while H2CO is predicted to peak closer to the ionization front than observed. In addition, the predicted SO abundance is higher than observed while the H2CO abundance is lower than observed. The discrepancies between the models and observations indicate that more sophisticated models, including production of H2CO through grain surface chemistry, are needed to quantitatively match the observations of this region.