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

TL;DR

This study investigates how cloud-cloud collision properties influence star formation efficiency across different galactic structures in NGC 3627, revealing that variations in collision velocity and GMC mass/density explain regional differences in star formation activity.

Contribution

It provides the first detailed analysis linking cloud collision parameters and galactic structural features to star formation efficiency in NGC 3627.

Findings

Higher star formation efficiency in the bar-end compared to the bar and disk.

Structural differences in collision velocity and GMC mass/density drive regional star formation variations.

CCC properties vary systematically with galactic structure, affecting star formation activity.

Abstract

While cloud-cloud collisions (CCCs) have been proposed as a mechanism for triggering massive star formation, it is suggested that higher collision velocities ($v_{\rm col}$) and lower GMC mass ($M_{\rm GMC}$) or/and density ($\Sigma_{\rm GMC}$) 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 ($m^\star_{\rm CCC}$ and $\epsilon_{\rm CCC}$) and explore the connections between $m^\star_{\rm CCC}$ and $\epsilon_{\rm CCC}$, $M_{\rm GMC}$($\Sigma_{\rm GMC}$) and $v_{\rm col}$, and galactic structures (disk, bar, and bar-end). Using ALMA CO(2--1) data (60~pc resolution), we estimated $v_{\rm col}$ 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 $m^\star_{\rm CCC}$ and $\epsilon_{\rm CCC}$ using attenuation-corrected H$\alpha$ data from VLT MUSE. We found that both $m^\star_{\rm CCC}$ and $\epsilon_{\rm CCC}$ are lower in the bar (median values: $10^{3.84}~M_\odot$ and $0.18~\%$), and higher in the bar-end ($10^{4.89}~M_\odot$ and $1.10~\%$) compared to the disk ($10^{4.28}~M_\odot$ and $0.75~\%$). Furthermore, we found that structural differences within the parameter space of $v_{\rm col}$ and $M_{\rm GMC}$($\Sigma_{\rm GMC}$), with higher $M_{\rm GMC}$($\Sigma_{\rm GMC}$) in the bar-end and higher $v_{\rm col}$ 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.