e-MERLIN resolves Betelgeuse at wavelength 5 cm

A. M. S. Richards (1); R. J. Davis (1); L. Decin (2); S. Etoka (1,3),; G. M. Harper (4) J. J. Lim (5,6); S. T. Garrington (1); M .D. Gray (1); I.; McDonald (1); E. O'Gorman (4); M. Wittkowski (7) ((1) JBCA; Dept. Physics and; Astronomy; University of Manchester; UK; (2) Instituut voor Sterrenkunde,; Katholieke Universiteit Leuven; Belgium (3) Hamburger Sternwarte; Germany,; (4) School of Physics; Trinity College; Dublin; Ireland; (5) Department of; Physics; University of Hong Kong; (6) Institute of Astronomy and; Astrophysics; Academia Sinica; Taipei; Taiwan; (7) ESO; Garching bei; Muenchen; Germany)

arXiv:1303.2864·astro-ph.SR·June 15, 2015

e-MERLIN resolves Betelgeuse at wavelength 5 cm

A. M. S. Richards (1), R. J. Davis (1), L. Decin (2), S. Etoka (1,3),, G. M. Harper (4) J. J. Lim (5,6), S. T. Garrington (1), M .D. Gray (1), I., McDonald (1), E. O'Gorman (4), M. Wittkowski (7) ((1) JBCA, Dept. Physics and, Astronomy, University of Manchester, UK

PDF

TL;DR

This study used e-MERLIN radio imaging to resolve Betelgeuse's photosphere at 5 cm, revealing hotspots with high brightness temperatures and an arc, providing insights into the star's atmospheric structure and mass-loss mechanisms.

Contribution

First high-resolution radio imaging of Betelgeuse's photosphere at 5 cm, detecting hotspots and atmospheric features that inform models of mass loss in red supergiants.

Findings

01

Detected hotspots with temperatures up to 5400 K.

02

Resolved an arc feature consistent with atmospheric extensions.

03

Observed hotspots at larger radii than previously seen in other regimes.

Abstract

Convection, pulsation and magnetic fields have all been suggested as mechanisms for the transport of mass and energy from the optical photosphere of red supergiants, out to the region where the stellar wind is launched. We imaged the red supergiant Betelgeuse at 0.06-0.18 arcsec resolution, using e-MERLIN at 5.5--6.0 GHz, with a sensitivity of ~0.01 mJy/beam. Most of the radio emission comes from within an ellipse (0.235x0.218) arcsec^2 (~5x the optical radius), with a flux density of 1.62 mJy, giving an average brightness temperature ~1250 K. This radio photosphere contains two hotspots of 0.53 and 0.79 mJy/beam, separated by 90 milli-arcsec, with brightness temperatures 5400+/-600 K and 3800+/-500 K. Similar hotspots, at more than double the distance from the photosphere of those seen in any other regime, were detected by the less-sensitive `old' MERLIN in 1992, 1995 and 1996 and many…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.