A Herschel study of YSO evolutionary stages and formation timelines in two fields of the Hi-GAL survey

TL;DR

This study uses Herschel data to analyze star-forming dust condensations in two Galactic Plane fields, revealing their evolutionary stages and formation timelines through spectral energy distribution modeling and ancillary data integration.

Contribution

It provides the first detailed characterization of YSO evolutionary stages and formation timelines in two specific Hi-GAL survey fields using multi-wavelength Herschel data.

Findings

Sources in the l=59° field are generally at earlier evolutionary stages.

Many cores are actively forming high-mass stars despite low surface densities.

The Lbol/Menv ratio varies widely, indicating diverse evolutionary phases.

Abstract

We present a first study of the star-forming compact dust condensations revealed by Herschel in the two 2 \times 2 \degr Galactic Plane fields centered at [l;b] = [30\degr; 0 \degr] and [l;b] = [59\degr; 0 \degr], respectively, and observed during the Science Demonstration Phase for the Herschel infrared Galactic Plane survey (Hi-GAL) Key-Project. Compact source catalogs extracted for the two fields in the five Hi-GAL bands (70, 160, 250, 350 and 500 $\mu$m) were merged based on simple criteria of positional association and spectral energy distribution (SED) consistency into a final catalog which contains only coherent SEDs with counterparts in at least three adjacent Herschel bands. These final source lists contain 528 entries for the l = 30\degr field, and 444 entries for the l = 59\degr field. The SED coverage has been augmented with ancillary data at 24 $\mu$m and 1.1 mm. SED modeling for the subset of 318 and 101 sources (in the two fields, respectively) for which the distance is known was carried out using both a structured star/disk/envelope radiative transfer model and a simple isothermal grey-body. Global parameters like mass, luminosity, temperature and dust properties have been estimated. The Lbol/Menv ratio spans four orders of magnitudes from values compatible with the pre-protostellar phase to embedded massive zero-age main sequence stars. Sources in the l = 59\degr field have on average lower L/M, possibly outlining an overall earlier evolutionary stage with respect to the sources in the l = 30\degr field. Many of these cores are actively forming high-mass stars, although the estimated core surface densities appear to be an order of magnitude below the 1 g cm$^{-2}$ critical threshold for high-mass star formation.