Stellar coronal magnetic fields and star-planet interaction

TL;DR

This paper presents a magnetic field model explaining star-planet interactions, linking observed stellar hot spots, flux enhancements, and coronal structures to magnetic topology changes caused by planetary influence.

Contribution

It introduces a novel magnetic field model that accounts for the intermittent nature of star-planet interactions and predicts observable phenomena like prominence structures and radio emissions.

Findings

Star-planet magnetic interactions can trigger energy releases in stellar coronae.

The model explains higher X-ray luminosity in stars with close-in planets.

Conditions for detecting planetary radio emissions are identified.

Abstract

Evidence of magnetic interaction between late-type stars and close-in giant planets is provided by the observations of stellar hot spots rotating synchronously with the planets and showing an enhancement of chromospheric and X-ray fluxes. We investigate star-planet interaction in the framework of a magnetic field model of a stellar corona, considering the interaction between the coronal field and that of a planetary magnetosphere moving through the corona. The energy budget of the star-planet interaction is discussed assuming that the planet may trigger a release of the energy of the coronal field by decreasing its relative helicity. The observed intermittent character of the star-planet interaction is explained by a topological change of the stellar coronal field, induced by a variation of its relative helicity. The model predicts the formation of many prominence-like structures in the case of highly active stars owing to the accumulation of matter evaporated from the planet inside an azimuthal flux rope in the outer corona. Moreover, the model can explain why stars accompanied by close-in planets have a higher X-ray luminosity than those with distant planets. It predicts that the best conditions to detect radio emission from the exoplanets and their host stars are achieved when the field topology is characterized by field lines connected to the surface of the star, leading to a chromospheric hot spot rotating synchronously with the planet. The main predictions of the model can be verified with present observational techniques, by a simultaneous monitoring of the chromospheric flux and X-ray (or radio) emission, and spectropolarimetric observations of the photospheric magnetic fields.