Fragmented atomic shell around S187 HII region and its interaction with molecular and ionized gas

TL;DR

This study investigates the complex atomic and molecular environment of the S187 H II region, revealing a fragmented, clumpy atomic shell with active star formation and dynamic interactions between gas phases.

Contribution

First detailed analysis of the fragmented atomic shell structure and its interaction with molecular gas in the S187 H II region.

Findings

Discovered a clumpy HI environment in the photodissociation region.

Estimated atomic mass fraction of the shell as ~260 M_sun.

Identified multiple stages of star formation within the shell.

Abstract

The environment of S187, a nearby H II region (1.4$\pm$0.3 kpc), is analyzed. A surrounding shell has been studied in the H I line, molecular lines, and also in infrared and radio continua. We report the first evidence of a clumpy HI environment in its photodissociation region. A background radio galaxy enables the estimation of the properties of cold atomic gas. The estimated atomic mass fraction of the shell is $\sim$260~M$_{\odot}$, the median spin temperature is $\sim$50~K, the shell size is $\sim$4 pc with typical wall width around 0.2 pc. The atomic shell consists of $\sim$100 fragments. The fragment sizes correlate with mass with a power-law index of 2.39-2.50. The S187 shell has a complex kinematical structure, including the expanding quasi spherical layer, molecular envelope, an atomic sub-bubble inside the shell and two dense cores (S187~SE and S187~NE) at different stages of evolution. The atomic sub-bubble inside the shell is young, contains a Class II young stellar object and OH maser in the centre and the associated YSOs in the walls of the bubble. S187~SE and S187~NE have similar masses ($\sim$1200~M$_\odot$ and $\sim$900~M$_\odot$, respectively). S187~SE is embedded into the atomic shell and has a number of associated objects including high mass protostars, outflows, maser sources and other indicators of ongoing star formation. No YSOs inside S187~NE were detected, but indications of compression and heating by the H II region exist.