Star formation timescale in the molecular filament WB 673

TL;DR

This study uses ammonia emission lines and astrochemical modeling to estimate the age of the molecular filament WB 673, suggesting rapid star formation within approximately 100,000 years.

Contribution

It provides the first chemical age estimate of WB 673 using multi-molecule analysis and astrochemical modeling, indicating a rapid star formation timescale.

Findings

Chemical age of WB 673 is 1-3 x 10^5 years.

Gas in the filament is relatively cold and dense.

Star formation occurs rapidly within ~10^5 years.

Abstract

We present observations of ammonia emission lines toward the interstellar filament WB~673 hosting the dense clumps WB~673, WB~668, S233-IR and G173.57+2.43. LTE analysis of the lines allows us to estimate gas kinetic temperature ($\lesssim$ 30~K in all the clumps), number density ($7-17\times10^3$~cm$^{-3}$), and ammonia column density ($\approx 1-1.5\times 10^{15}$~cm$^{-2}$) in the dense clumps. We find signatures of collapse in WB 673 and presence of compact spatially unresolved dense clumps in S233-IR. We reconstruct 1D density and temperature distributions in the clumps and estimate their ages using astrochemical modelling. Considering CO, CS, NH$_3$ and N$_2$H$^+$ molecules (plus HCN and HNC for WB~673), we find a chemical age of $t_{\rm chem}=1-3\times 10^5$~yrs providing the best agreement between the simulated and observed column densities in all the clumps. Therefore, we consider $t_{\rm chem}$ as the chemical age of the entire filament. A long preceding low-density stage of gas accumulation in the astrochemical model would break the agreement between the simulated and observed column densities. We suggest that rapid star formation over a $\sim 10^5$~yrs timescale take place in the filament.