Temporal Evolution of the Size and Temperature of Betelgeuse's Extended Atmosphere

TL;DR

This study uses multi-epoch radio observations to analyze the size, temperature, and asymmetry of Betelgeuse's extended atmosphere, finding temperature profiles, variability, and correlations with stellar pulsations over 12 years.

Contribution

It provides the first multi-epoch spatially resolved measurements of Betelgeuse's extended atmosphere at multiple wavelengths, clarifies the nature of radio hotspots, and links atmospheric variability to stellar pulsations.

Findings

Extended atmosphere deviates from circular symmetry.

Temperature decreases from 3000 K at 2 R* to 1800 K at 6 R*.

Correlation between V band flux variability and radio fluxes.

Abstract

We use the Very Large Array (VLA) in the A configuration with the Pie Town (PT) Very Long Baseline Array (VLBA) antenna to spatially resolve the extended atmosphere of Betelgeuse over multiple epochs at 0.7, 1.3, 2.0, 3.5, and 6.1 cm. The extended atmosphere deviates from circular symmetry at all wavelengths while at some epochs we find possible evidence for small pockets of gas significantly cooler than the mean global temperature. We find no evidence for the recently reported e-MERLIN radio hotspots in any of our multi-epoch VLA/PT data, despite having sufficient spatial resolution and sensitivity at short wavelengths, and conclude that these radio hotspots are most likely interferometric artefacts. The mean gas temperature of the extended atmosphere has a typical value of 3000 K at 2 $R_{\star}$ and decreases to 1800 K at 6 $R_{\star}$, in broad agreement with the findings of the single epoch study from Lim et al. (1998). The overall temperature profile of the extended atmosphere between $2 R_{\star} \lesssim r \lesssim 6 R_{\star}$ can be described by a power law of the form $T_{\mathrm{gas}}(r) \propto r^{-0.6}$, with temporal variability of a few 100 K evident at some epochs. Finally, we present over 12 years of V band photometry, part of which overlaps our multi-epoch radio data. We find a correlation between the fractional flux density variability at V band with most radio wavelengths. This correlation is likely due to shock waves induced by stellar pulsations, which heat the inner atmosphere and ionize the more extended atmosphere through radiative means. Stellar pulsations may play an important role in exciting Betelgeuse's extended atmosphere.