Distances and statistics of local molecular clouds in the first Galactic quadrant

TL;DR

This study analyzes local molecular clouds in the first Galactic quadrant using MWISP CO survey data, determining their distances, properties, and distributions, revealing power-law behaviors in cloud area and mass.

Contribution

It introduces a method combining Gaia DR2 parallaxes and CO survey data to accurately determine distances and properties of local molecular clouds.

Findings

Distances range from 250 pc to 1.5 kpc with a linear velocity-distance relation.

Molecular cloud area and mass follow power-law distributions.

Kinematic distances tend to be systematically larger for local clouds.

Abstract

We present an analysis of local molecular clouds (-6 <VLSR< 30 km/s, i.e., <1.5 kpc) in the first Galactic quadrant (25.8{\deg} <l<49.7{\deg} and |b|<5{\deg}), a pilot region of the Milky Way Imaging Scroll Painting (MWISP) CO survey. Using the SCIMES algorithm to divide large molecular clouds into moderate-sized ones, we determined distances to 28 molecular clouds with the background-eliminated extinction-parallax (BEEP) method using the Gaia DR2 parallax measurements aided by AG and AV, and the distance ranges from 250 pc to about 1.5 kpc. These incomplete distance samples indicate a linear relationship between the distance and the radial velocity (VLSR) with a scatter of 0.16 kpc, and kinematic distances may be systematically larger for local molecular clouds. In order to investigate fundamental properties of molecular clouds, such as the total sample number, the linewidth, the brightness temperature, the physical area, and the mass, we decompose the spectral cube using the DBSCAN algorithm. Post selection criteria are imposed on DBSCAN clusters to remove the noise contamination, and we found that the separation of molecular cloud individuals is reliable based on a definition of independent consecutive structures in l-b-V space. The completeness of the local molecular cloud flux collected by the MWISP CO survey is about 80%. The physical area, A, shows a power-law distribution, dN/dA \propto A^{-2.20+/-0.18}, while the molecular cloud mass also follows a power-law distribution but slightly flatter, dN/dM \propto M^{-1.96+/-0.11}.