The molecular environment of the solar-type protostar IRAS 16293-2422

TL;DR

This study uses submillimeter observations to map the molecular environment of the low-mass protostar IRAS 16293-2422, revealing complex morphology, temperature, and chemical variations crucial for understanding early star formation.

Contribution

First detailed molecular line imaging of IRAS 16293-2422's environment across a broad frequency range, revealing complex structures and chemical differences.

Findings

Identified 144 molecular transitions from 36 species.

Confirmed outflow interaction with the prestellar core 16293E.

Detected temperature and chemical variations across the region.

Abstract

Studying the physical and chemical processes leading to the formation of low-mass stars is crucial for understanding the origin of our Sun and the Solar System. In particular, analyzing the emission and absorption lines from molecules is a fundamental tool to obtain information on the kinematics and chemistry at the very early stages of star formation. In this work we aim to examine the spatial structures and molecular abundances of material surrounding the very well-known low-mass binary protostar IRAS 16293-2422 and the prestellar core 16293E, which are embedded in the Lynds 1689N dark cloud. We have used the LAsMA heterodyne array installed on the Atacama Pathfinder EXperiment (APEX) 12 meter submillimeter telescope to image a region of about 0.12x0.12pc$^2$ around IRAS 16293-2422 and 16293E and to study their molecular environment covering 45.6GHz in a frequency range from 277GHz to 375GHz. We have identified 144 transitions from 36 molecular species, including isotopologues. The maps reveal the envelope to have a complex morphology around the cloud cores and the emission peaks known as E1, E2, W1, W2, and HE2, including the outflow structure arising from IRAS 16293-2422. Using several transitions of para-H$_2$CO, we have derived new lower limits for the kinetic temperatures toward IRAS 16293-2422 and the surrounding emission peaks. Based on these temperatures, H$_2$ volume densities and column densities for all detected species were derived around the cloud cores and all emission peaks. Our new observations further confirm the scenario of an outflow arising from IRAS 16293-2422 interacting with the prestellar core 16293E. We observe a large-scale velocity gradient across the molecular cloud. Furthermore, we see clear chemical differences at the examined positions. The data suggests that emission peak W2 may be related to a colder dust source.