Structural Variation of Molecular Gas in the Sagittarius Arm and Inter-Arm Regions

TL;DR

This study maps molecular gas in the Sagittarius arm and inter-arm regions, revealing how gas structures and physical conditions vary across the spiral arm, with implications for star formation processes.

Contribution

It introduces the brightness distribution function and index (BDI) to quantify molecular gas structures and their variation across spiral arms.

Findings

Bright, compact structures are associated with spiral arm velocities.

Diffuse, extended emission dominates in inter-arm regions.

Gas structure changes across the spiral arm, influencing star formation locations.

Abstract

We have carried out survey observations toward the Galactic plane at l~38 deg in the 12CO and 13CO J=1-0 lines using the Nobeyama Radio Observatory 45-m telescope. A wide area (0.8 x 0.8 deg) was mapped with high spatial resolution (17"). The line of sight samples the gas in both the Sagittarius arm and the inter-arm regions. The present observations reveal how the structure and physical conditions vary across a spiral arm. We classify the molecular gas in the line of sight into two distinct components based on its appearance: the bright and compact B component and the fainter and diffuse (i.e., more extended) D component. The B component is predominantly seen at the spiral arm velocities, while the D component dominates at the inter-arm velocities and is also found at the spiral arm velocities. We introduce the brightness distribution function and the brightness distribution index (BDI, which indicates the dominance of the B component) in order to quantify the map's appearance. The radial velocities of BDI peaks coincide with those of high 12CO J=3-2/12CO J=1-0 intensity ratio (i.e., warm gas) and H II regions, and tend to be offset from the line brightness peaks at lower velocities (i.e., presumably downstream side of the arm). Our observations reveal that the gas structure at small scales changes across a spiral arm: bright and spatially confined structures develop in a spiral arm, leading to star formation at downstream side, while extended emission dominates in the inter-arm region.