Monitoring observations of 6.7 GHz methanol masers

TL;DR

This study monitored 6.7 GHz methanol masers in 139 star-forming regions over several years, revealing diverse variability patterns, bursts, and correlations that shed light on the physical mechanisms driving maser activity.

Contribution

It provides the first extensive multi-year monitoring of methanol masers, highlighting variability characteristics and their relation to the properties of the exciting sources.

Findings

80% of sources show >10% variability over weeks to years

Detection of synchronized and anti-correlated spectral feature variations

Identification of long-lasting and rapid bursts in maser features

Abstract

We report results of 6.7 GHz methanol maser monitoring of 139 star-forming sites with the Torun 32 m radio telescope from June 2009 to February 2013. The targets were observed at least once a month, with higher cadences of 2-4 measurements per week for circumpolar objects. Nearly 80 percent of the sources display variability greater than 10 per cent on a time-scale between a week and a few years but about three quarters of the sample have only 1-3 spectral features which vary significantly. Irregular intensity fluctuation is the dominant type of variability and only nine objects show evidence for cyclic variations with periods of 120 to 416 d. Synchronised and anti-correlated variations of maser features are detected in four sources with a disc-like morphology. Rapid and high amplitude bursts of individual features are seen on 3-5 occasions in five sources. Long (>50 d to 20 months) lasting bursts are observed mostly for individual or groups of features in 19 sources and only one source experienced a remarkable global flare. A few flaring features display a strong anti-correlation between intensity and line-width that is expected for unsaturated amplification. There is a weak anti-correlation between the maser feature luminosity and variability measure, i.e. maser features with low luminosity tend to be more variable than those with high luminosity. The analysis of the spectral energy distribution and continuum radio emission reveals that the variability of the maser features increases when the bolometric luminosity and Lyman flux of the exciting object decreases. Our results support the concept of a major role for infrared pumping photons in triggering outburst activity of maser emission.