Magnetic field structure in single late-type giants: The effectively single giant V390 Aur

TL;DR

This study uses spectropolarimetry and Zeeman Doppler Imaging to map the magnetic field of the giant star V390 Aur, revealing complex magnetic structures and suggesting an efficient stellar dynamo mechanism.

Contribution

The paper presents the first detailed magnetic field map of V390 Aur using ZDI, combining spectropolarimetric data with stellar modeling to understand its magnetic activity.

Findings

Magnetic map shows a polar spot and lower latitude negative spots.

Presence of a high-latitude azimuthal field belt indicates a toroidal component.

Activity indicators suggest slower chromospheric rotation than the photosphere.

Abstract

We have studied the active giant V390 Aur using spectropolarimetry to obtain direct and simultaneous measurements of the magnetic field and the activity indicators in order to get a precise insight of its activity. We used the spectropolarimeter NARVAL at the Bernard Lyot Telescope (Observatoire du Pic du Midi, France) to obtain a series of Stokes I and Stokes V profiles. The Least Square deconvolution (LSD) technique was applied to detect the Zeeman signature of the magnetic field in each of our 13 observations and to measure its longitudinal component. We could also monitor the CaII K & H and IR triplet, as well as the H_alpha lines which are activity indicators. In order to reconstruct the magnetic field geometry of V390 Aur, we applied the Zeeman Doppler Imaging (ZDI) inversion method and present a map for the magnetic field. Based on the obtained spectra, we also refined the fundamental parameters of the star and the Li abundance. The ZDI revealed a structure in the radial magnetic field consisting of a polar magnetic spot of positive polarity and several negative spots at lower latitude. A high latitude belt is present on the azimuthal field map, indicative of a toroidal field close to the surface. It was found that the photometric period cannot fit the behaviour of the activity indicators formed in the chromosphere. Their behaviour suggests slower rotation compared to the photosphere, but our dataset is too short to be able to estimate the exact periods for them.Accepted for publication in A&A All these results can be explained in terms of an \alpha-\omega dynamo operation, taking into account the stellar structure and rotation properties of V390 Aur that we study using up to-date stellar models computed at solar metallicity. The calculated Rossby number also points to a very efficient dynamo