Detection of coherent low-frequency radio bursts from weak-line TTauri stars

TL;DR

This study reports the first detection of low-frequency coherent radio bursts from T Tauri stars, indicating strong magnetic activity and likely electron-cyclotron maser emission driven by stellar magnetosphere processes.

Contribution

It provides the first evidence of low-frequency coherent radio emission from T Tauri stars, expanding understanding of stellar magnetic activity beyond main-sequence stars.

Findings

Detected bright radio bursts at 150 MHz from two T Tauri stars

High brightness temperatures and polarization suggest coherent emission, likely ECM

Magnetic fields in emission regions estimated at 40-70 G

Abstract

In recent years, thanks to new facilities such as LOFAR capable of sensitive observations, much work has been done on the detection of stellar radio emission at low frequencies. Such emission has commonly been shown to be coherent emission, generally attributed to electron-cyclotron maser emission, and has usually been detected from main-sequence M dwarfs. Here we report the first detection of coherent emission at low frequencies from T Tauri stars, which are known to be associated with high levels of stellar activity. Using LOFAR, we have detected several bright radio bursts at 150 MHz from two weak-line T Tauri stars: KPNO-Tau 14 and LkCa 4. All of the bursts have high brightness temperatures ($10^{13} - 10^{14}\ \mathrm{K}$) and high circular polarization fractions (60 - 90 \%), indicating that they must be due to a coherent emission mechanism. This could be either plasma emission or electron-cyclotron maser (ECM) emission. Due to the exceptionally high brightness temperatures seen in at least one of the bursts ($\geq 10^{14}\ \mathrm{K}$), and the high circular polarization levels, it seems unlikely that plasma emission could be the source and so ECM is favoured as the most likely emission mechanism. Assuming this is the case, the required magnetic field in the emission regions would be 40 - 70 G. We determine that the most likely method of generating ECM emission is plasma co-rotation breakdown in the stellar magnetosphere. There remains the possibility, however, it could be due to an interaction with an orbiting exoplanet.