Properties of $\mathrm{H_2O}$ masers and their associated sources in Sagittarius B2

TL;DR

This study uses high-resolution VLA observations to analyze 499 water masers in Sagittarius B2, revealing their associations with protostellar cores, HII regions, and outflows, and providing insights into star formation processes.

Contribution

It offers a detailed spatial and kinematic analysis of H2O masers in Sagittarius B2, classifying their origins and relation to star-forming activities, which advances understanding of maser environments.

Findings

62% of masers are associated with protostellar cores

Outflow-associated masers are confined within 2000 au of sources

Protostellar cores with masers tend to have brighter 3 mm continuum

Abstract

We present high-resolution Karl G. Jansky Very Large Array observations of the 22 GHz $\mathrm{H_2O}$ maser line in the extended Sagittarius B2 cloud. We detect 499 $\mathrm{H_2O}$ masers across the observed velocities between -39 and 172 km s$^{-1}$. To investigate the nature of the masers, we analyze their spatial distribution and cross-match with catalogs of HII regions and protostellar cores. 62% of masers are associated with protostellar cores and 32% with HII regions. The nature of the remaining 6% of sources was not established, but is likely associated with protostellar cores. Based on the spatial extent of the groups of masers, we classify them as either outflow-associated or young stellar object (YSO)-associated. We identify 144 unique sites of maser emission: 23 are associated with HII regions and 94 with protostellar cores, of which 33 are associated with protostellar outflows and 18 with YSOs. The outflow-associated $\mathrm{H_2O}$ maser emission is confined to within $<2000$ au of the central continuum source, despite shocked SiO emission extending over tens of thousands of au. The YSO-associated masers show a lack of detections at $5 < V_{rel} < 30$ km s$^{-1}$, which we suggest may be due to maser self-absorption. We show how $\mathrm{H_2O}$ masers trace the large-scale material flow in Sgr B2 N (North) also seen in SiO and mm continuum emission. Finally, we find that protostellar cores with associated $\mathrm{H_2O}$ masers tend to have brighter 3 mm continuum emission on average, although there is no strong correlation between maser brightness and continuum flux.