Modelling carbon chain and complex organic molecules in the DR21(OH) clump

TL;DR

This study uses wide-band spectral observations and modeling to analyze the physical and chemical environment of high-mass star formation in DR21(OH), revealing multiple temperature components and dominant grain chemistry routes for complex molecules.

Contribution

It provides a comprehensive multi-component analysis of molecular emissions in DR21(OH), combining LTE, non-LTE, and chemical models to understand molecule formation and environmental structure.

Findings

Identification of warm and cold components in dense clumps.

Thermal processes explain H2CO and CH3CCH abundances.

Non-thermal processes are necessary for CH3OH formation.

Abstract

Star-forming regions host a large and evolving suite of molecular species. Molecular transition lines, particularly of complex molecules, can reveal the physical and dynamical environment of star formation. We aim to study the large-scale structure and environment of high-mass star formation through single-dish observations of CH$_3$CCH, CH$_3$OH, and H$_2$CO. We have conducted a wide-band spectral survey with the IRAM 30-m telescope and the 100-m GBT towards the high-mass star-forming region DR21(OH)/N44. We use a multi-component local thermodynamic equilibrium model to determine the large-scale physical environment near DR21(OH) and the surrounding dense clumps. We follow up with a radiative transfer code for CH$_3$OH to look at non-LTE behaviour. We then use a gas-grain chemical model to understand the formation routes of these molecules in their observed environments. We disentangle multiple components of DR21(OH) in each of the three molecules. We find a warm and cold component each towards the dusty condensations MM1 and MM2, and a fifth broad, outflow component. We also reveal warm and cold components towards other dense clumps in our maps: N40, N36, N41, N38, and N48. We find thermal mechanisms are adequate to produce the observed abundances of H$_2$CO and CH$_3$CCH while non-thermal mechanisms are needed to produce CH$_3$OH. Through a combination of wide-band mapping observations, LTE and non-LTE model analysis, and chemical modelling, we disentangle the different velocity and temperature components within our clump-scale beam, a scale that links a star-forming core to its parent cloud. We find numerous warm, 20-80 K components corresponding to known cores and outflows in the region. We determine the production routes of these species to be dominated by grain chemistry.