http://arxiv.org/abs/2303.15499

Context: Core accretion models of massive star formation require the existence of massive, starless cores within molecular clouds. Yet, only a small number of candidates for such truly massive, monolithic cores are currently known. Aims: Here, we analyse a massive core in the well-studied infrared dark cloud (IRDC) called the “dragon cloud” (G028.37+00.07 or “Cloud C”). This core (C2c1) sits at the end of a chain of a roughly equally spaced actively star-forming cores near the center of the IRDC. Methods: We present new high-angular resolution 1 mm ALMA dust continuum and molecular line observations of the massive core. Results: The high-angular resolution observations show that this region fragments into two cores C2c1a and C2c1b, which retain significant background subtracted masses of 23 Msun and 2 Msun (31 Msun and 6 Msun without background subtraction), respectively. The cores do not appear to fragment further on the scales of our highest angular resolution images (0.200 arcsec, 0.005 pc ~ 1000 AU). We find that these cores are very dense (nH2 > 10^6 cm-3) and have only trans-sonic non-thermal motions (Ms ~ 1). Together the mass, density and internal motions imply a virial parameter of < 1, which suggests the cores are gravitationally unstable, unless supported by strong magnetic fields with strengths of ~ 1 – 10 mG. From CO line observations, we find that there is tentative evidence for a weak molecular outflow towards the lower-mass core, yet the more massive core remains devoid of any star formation indicators. Conclusions: We have presented evidence for the existence of a massive, prestellar core, which has implications for theories of massive star formation. This source warrants follow-up higher-angular resolution observations to further assess its monolithic and prestellar nature.

Read this paper on arXiv…

A. Barnes, J. Liu, Q. Zhang, et. al.
Wed, 29 Mar 23
10/73

Comments: 8+4 pages, 4+2 Figures, 2 Tables, accepted for publication in Astronomy & Astrophysics