Galactic structure dependence of cloud-cloud collisions driven star formation in the barred galaxy NGC 3627

Abstract

While cloud-cloud collisions (CCCs) have been proposed as a mechanism for triggering massive star formation, it is suggested that higher collision velocities (v col) and lower GMC mass (M GMC) or/and density ( GMC) tend to suppress star formation. In this study, we choose the nearby barred galaxy NGC 3627 to examine the SFR and SFE of a colliding GMC (m CCC and ε CCC) and explore the connections between m CCC and ε CCC, M GMC( GMC) and v col, and galactic structures (disk, bar, and bar-end). Using ALMA CO(2--1) data (60~pc resolution), we estimated v col within 500~pc apertures, based on line-of-sight GMC velocities, assuming random motion in a two-dimensional plane. We extracted apertures where at least 0.1 collisions occur per 1 Myr, identifying them as regions dominated by CCC-driven star formation, and then calculated m CCC and ε CCC using attenuation-corrected Hα data from VLT MUSE. We found that both m CCC and ε CCC are lower in the bar (median values: 103.84~M and 0.18~\%), and higher in the bar-end (104.89~M and 1.10~\%) compared to the disk (104.28~M and 0.75~\%). Furthermore, we found that structural differences within the parameter space of v col and M GMC( GMC), with higher M GMC( GMC) in the bar-end and higher v col in the bar compared to the disk, lead to higher star formation activity in the bar-end and lower activity in the bar. Our results support the scenario that variations in CCC properties across different galactic structures can explain the observed differences in SFE on a kpc scale within a disk galaxy.

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