Resolved ISM properties and scaling relations in the barred galaxy NGC 3627: constraints from NIKA2 observations

TL;DR

This study uses new millimeter observations to analyze the ISM, dust, and star formation in NGC 3627, revealing how dynamical processes influence galaxy evolution and dust properties.

Contribution

It provides detailed ISM property measurements and scaling relations in NGC 3627 using multi-wavelength data and spectral energy distribution fitting, highlighting the impact of dynamical processes.

Findings

Radio emission peaks at 18% in the southern bar-end.

Small dust grains constitute about 13% of dust mass and are depleted in intense radiation fields.

The 160 μm emission correlates strongly with molecular gas.

Abstract

We investigate the interplay between star formation, interstellar medium (ISM) components, and dust properties in NGC 3627 using new NIKA2 1.15 and 2 mm observations from the IMEGIN Large Program. Our goal is to analyze dust and radio emission, decompose contributions in the millimeter-centimeter regime, and explore ISM properties within the galaxy. We perform spectral energy distribution fitting, at both global and spatial scales, using the THEMIS dust model within the HerBIE code, applied to data from 3.4 $\mu$m to 6 cm. We decompose emission into dust, free-free, and synchrotron components, and examine correlations with gas surface density and star formation activity. Additionally, we analyze the small dust grain fraction and its variation across the galaxy. We find $\sim$10% radio emission at 2 mm, peaking at 18% in the southern bar-end, which hosts the highest star formation activity. However, an isolated star-forming region beyond this bar-end is the most efficient, as indicated by its elevated dust production efficiency and effective yield, predicted by our simplistic dust evolution model. The 160 $\mu$m emission shows the strongest correlation with molecular gas, while 1.15 mm better traces the dust mass surface density. Small grains, which make up $\sim$13% of dust mass (2 $\times$ 10$^{7}$ M$_{\odot}$), are depleted in intense radiation fields, with a notable deficit in the southern tidal tail. ISM properties and chemical evolution indicate that dynamical processes, such as bar-driven gas flows and tidal interactions, are crucial in shaping the galactic structure, influencing star formation efficiency, and dust distribution.