Evidence of Short Timescale Flux Density Variations of UC HII regions in Sgr B2 Main and North

TL;DR

This study presents high-resolution 7 mm observations of Sgr B2's ultracompact HII regions, revealing significant short-term flux density variations that challenge classical steady-expansion models and support dynamic, violent star formation processes.

Contribution

It provides the first high-resolution 7 mm data showing flux density changes in Sgr B2's HII regions, indicating variable accretion during massive star formation.

Findings

K2-North flux decreased by ~27% between 2001 and 2012

F3c-Main flux increased by ~30% between 2003 and 2012

Flux variations suggest non-steady, dynamic star formation processes

Abstract

We have recently published observations of significant flux density variations at 1.3 cm in HII regions in the star forming regions Sgr B2 Main and North (De Pree et al. 2014). To further study these variations, we have made new 7 mm continuum and recombination line observations of Sgr B2 at the highest possible angular resolution of the Karl G. Jansky Very Large Array (VLA). We have observed Sgr B2 Main and North at 42.9 GHz and at 45.4 GHz in the BnA configuration (Main) and the A configuration (North). We compare these new data to archival VLA 7 mm continuum data of Sgr B2 Main observed in 2003 and Sgr B2 North observed in 2001. We find that one of the 41 known ultracompact and hypercompact HII regions in Sgr B2 (K2-North) has decreased $\sim$27% in flux density from 142$\pm$14 mJy to 103$\pm$10 mJy (2.3$\sigma$) between 2001 and 2012. A second source, F3c-Main has increased $\sim$30% in flux density from 82$\pm$8 mJy to 107 $\pm$11 mJy (1.8$\sigma$) between 2003 and 2012. F3c-Main was previously observed to increase in flux density at 1.3 cm over a longer time period between 1989 and 2012 (De Pree et al. 2014). An observation of decreasing flux density, such as that observed in K2-North, is particularly significant since such a change is not predicted by the classical hypothesis of steady expansion of HII regions during massive star accretion. Our new observations at 7 mm, along with others in the literature, suggest that the formation of massive stars occurs through time-variable and violent accretion.