Abstract
We have undertaken a Parkes ammonia spectral line study, in the lowest two inversion transitions, of southern massive star formation regions, including young massive candidate protostars, with the aim of characterising the earliest stages of massive star formation. 138 sources from the submillimetre continuum emission studies of Hill et al., were found to have robust (1,1) detections, including two sources with two velocity components, and 102 in the (2,2) transition. We determine the ammonia line properties of the sources: linewidth, flux density, kinetic temperature, NH$_3$ column density and opacity, and revisit our SED modelling procedure to derive the mass for 52 of the sources. By combining the continuum emission information with ammonia observations we substantially constrain the physical properties of the high-mass clumps. There is clear complementarity between ammonia and continuum observations for derivations of physical parameters. The MM-only class, identified in the continuum studies of Hill et al., display smaller sizes, mass and velocity dispersion and/or turbulence than star-forming clumps, suggesting a quiescent prestellar stage and/or the formation of less massive stars.
Highlights
Massive stars are dynamical and enigmatic powerhouses that shape and drive both their local stellar neighbourhood and the ecology and evolution of their host galaxy
We have undertaken an ammonia molecular line study, in the lowest two inversion transitions, of young massive star formation (MSF) regions in the southern hemisphere as part of an effort to characterize the earliest stages of high-mass star formation
244 sources were observed in both ammonia transitions, using the Parkes radio telescope
Summary
Massive stars are dynamical and enigmatic powerhouses that shape and drive both their local stellar neighbourhood and the ecology and evolution of their host galaxy. Despite this heavy influence, the formation and evolution of a massive star is not well understood. Perplexing are the earliest evolutionary stages of massive star formation (MSF). The difficulty lies in the unambiguous detection, identification and characterization of these stages, snapshots of which are difficult to obtain as a result of the general rarity of candidates and the rapidity of their evolution (Garay & Lizano 1999). Whether or not massive stars are scaled-up analogues of lowmass stars is still uncertain. Massive stars exert considerable radiative pressure on the surrounding dust and gas, which in principle
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