ALMASOP: Detection of Turbulence-induced Mass Assembly Shocks in Starless Cores

ALMASOP: Detection of Turbulence-induced Mass Assembly Shocks in Starless Cores

Star formation is a series of mass assembly processes and starless cores; those cold and dense condensations in molecular clouds play a pivotal role as initial seeds of stars. With only a limited sample of known starless cores, however, the origin and growth of such stellar precursors had not been w...

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Main Authors: Shih-Ying Hsu, Sheng-Yuan Liu, Xunchuan Liu, Pak Shing Li, Tie Liu, Dipen Sahu, Ken'ichi Tatematsu, Shanghuo Li, Naomi Hirano, Chin-Fei Lee, Sheng-Jun Lin
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:The Astrophysical Journal Letters
Subjects:
Radio astronomy
Star formation
Magnetohydrodynamics
Complex organic molecules
Low mass stars
Shocks
Online Access:https://doi.org/10.3847/2041-8213/adcd6a
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Summary:Star formation is a series of mass assembly processes and starless cores; those cold and dense condensations in molecular clouds play a pivotal role as initial seeds of stars. With only a limited sample of known starless cores, however, the origin and growth of such stellar precursors had not been well characterized previously. Meanwhile, the recent discovery of CH _3 OH emission, which is generally associated with the desorbed icy mantle in warm regions, particularly at the periphery of starless cores, also remains puzzling. We present sensitive Atacama Large Millimeter/submillimeter Array (Band 3) observations (at 3 mm) toward a sample of newly identified starless cores in the Orion molecular cloud. The spatially resolved images distinctly indicate that the observed CH _3 OH and N _2 H ^+ emission associated with these cores are morphologically anticorrelated and kinematically offset from each other. We postulate that the CH _3 OH emission highlights the desorption of icy mantle by shocks resulting from gas piling onto dense cores in the filaments traced by N _2 H ^+ . Our magnetohydrodynamic simulations of star formation in turbulent clouds combined with radiative transfer calculations and imaging simulations successfully reproduced the observed signatures and reaffirmed the above scenario at work. Our result serves as an intriguing and exemplary illustration, a snapshot in time, of the dynamic star-forming processes in turbulent clouds. The results offer compelling insights into the mechanisms governing the growth of starless cores and the presence of gas-phase complex organic molecules associated with these cores.
ISSN:2041-8205

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