Initial Fragmentation in the Infrared Dark Cloud G28.53-0.25

TL;DR

This study investigates the fragmentation and star formation potential of dense cores in the IRDC G28.53-0.25 using multi-wavelength data, revealing gravitationally bound cores and the star-forming status of different clumps.

Contribution

It provides detailed physical characterization of dense cores in an IRDC, highlighting the role of turbulence and gravity in core support and star formation.

Findings

Twelve dense cores identified at 0.1 pc scale.

Turbulent pressure supports fragmentation at 1 pc scale.

Some cores are gravitationally bound and actively forming stars.

Abstract

To study the fragmentation and gravitational collapse of dense cores in infrared dark clouds (IRDCs), we have obtained submillimeter continuum and spectral line data as well as multiple inversion transitions of NH3 and H2O maser data of four massive clumps in an IRDC G28.53-0.25. Combining single dish and interferometer NH3 data, we derive the rotation temperature of G28.53. We identity 12 dense cores at 0.1 pc scale based on submillimeter continuum, and obtain their physical properties using NH3 and continuum data. By comparing the Jeans masses of cores with the core masses, we find that turbulent pressure is important in supporting the gas when 1 pc scale clumps fragment into 0.1 pc scale cores. All cores have a virial parameter smaller than 1 assuming a inverse squared radial density profile, suggesting they are gravitationally bound, and the three most promising star forming cores have a virial parameter smaller than 1 even taking magnetic field into account. We also associate the cores with star formation activities revealed by outflows, masers, or infrared sources. Unlike what previous studies suggested, MM1 turns out to harbor a few star forming cores and is likely a progenitor of high-mass star cluster. MM5 is intermediate while MM7/8 are quiescent in terms of star formation, but they also harbor gravitationally bound dense cores and have the potential of forming stars as in MM1.