Dense gas tracers in and between spiral arms: from Giant Molecular Filaments to star-forming clumps

TL;DR

This study maps dense gas tracers in giant molecular filaments within our galaxy, revealing how different tracers and spatial resolutions influence our understanding of star-forming regions across spiral arms and interarm areas.

Contribution

It provides new insights into the effectiveness of various dense gas tracers and highlights the importance of spatial resolution in studying molecular environments in galaxies.

Findings

N$_2$H$^+$ best traces truly dense gas.

Significant emission differences between arm and interarm regions.

Variations within filaments often exceed those between arm and interarm.

Abstract

Giant Molecular Filaments are opportune locations in our Galaxy to study the star-forming interstellar matter and its accumulation on spatial scales comparable to those now becoming available for external galaxies. We mapped the emission of HCN(1$-$0), HCO$^+$(1$-$0), and N$_2$H$^+$(1$-$0) towards two of these filaments, one associated with the Sagittarius arm and one with an interarm area. Using the data alongside the COHRS $^{12}$CO(3$-$2), the CHIMPS $^{13}$CO(3$-$2), and $\textit{Herschel}$-based column density maps, we evaluate the dense gas tracer emission characteristics and find that although its filling factor is the smallest among the studied species, N$_2$H$^+$ is the best at tracing the truly dense gas. Significant differences can be seen between the $^{13}$CO, HCN, and $N$(H$_2$)$_{\mathrm{dust}}$ levels of the arm and interarm, while the N$_2$H$^+$ emission is more uniform regardless of location, meaning that the observed variations in line ratios like N$_2$H$^+$/HCN or N$_2$H$^+$/$^{13}$CO are driven by species tracing moderate-density gas and not the star-forming gas. In many cases, greater variation in molecular emission and ratios exist between regions inside a filament than between the arm and interarm environments. The choice of measure of the dense gas and the available spatial resolution have deep impact on the multi-scale view of different environments inside a galaxy regarding molecular emissions, ratios, and thus the estimated star formation activity.