Characterising the physical and chemical properties of a young Class 0 protostellar core embedded in the Orion B9 filament

Abstract

The present study aims to characterise the physical and chemical properties of the protostellar core Orion B9-SMM3. The APEX telescope was used to perform a follow-up molecular line survey of SMM3. The following species were identified from the frequency range 218.2-222.2 GHz: 13CO, C18O, SO, para-H2CO, and E1-type CH3OH. The on-the-fly mapping observations at 215.1-219.1 GHz revealed that SMM3 is associated with a dense gas core as traced by DCO+ and p-H2CO. Altogether three different p-H2CO transitions were detected with clearly broadened linewidths (8.2-11 km s-1 in FWHM). The derived p-H2CO rotational temperature, 6415 K, indicates the presence of warm gas. We also detected a narrow p-H2CO line (FWHM=0.42 km s-1) at the systemic velocity. The p-H2CO abundance for the broad component appears to be enhanced by two orders of magnitude with respect to the narrow line value (3×10-9 versus 2×10-11). The detected methanol line shows a linewidth similar to those of the broad p-H2CO lines, which indicates their coexistence. The CO isotopologue data suggest that the CO depletion factor decreases from 272 towards the core centre to a value of 81 towards the core edge. In the latter position, the N2D+/N2H+ ratio is revised down to 0.140.06. The origin of the subfragments inside the SMM3 core we found previously can be understood in terms of the Jeans instability if non-thermal motions are taken into account. The estimated fragmentation timescale, and the derived chemical abundances suggest that SMM3 is a few times 105 yr old, in good agreement with its Class 0 classification inferred from the spectral energy distribution analysis. The broad p-H2CO and CH3OH lines, and the associated warm gas provide the first clear evidence of a molecular outflow driven by SMM3.