Hot Jupiters and stellar magnetic activity

Context. Recent observations suggest that stellar magnetic activity may be influenced by the presence of a close- by giant planet. Specifically, chromospheric hot spots rotating in phase with the planet orbital motion have been observed during some seasons in a few stars harbouring hot Jupiters. The spot leads the subplanetary point by a typical amount of similar to 60 degrees- 70 degrees., with the extreme case of. And where the angle is similar to 170 degrees. Aims. The interaction between the star and the planet is described considering the reconnection between the stellar coronal field and the magnetic field of the planet. Reconnection events produce energetic particles that, moving along magnetic field lines, impact onto the stellar chromosphere giving rise to a localized hot spot. Methods. A simple magnetohydrostatic model is introduced to describe the coronal magnetic field of the star connecting its surface to the orbiting planet. The field is assumed to be axisymmetric around the rotation axis of the star and its configuration is more general than a linear force- free field. Results. With a suitable choice of the free parameters, the model can explain the phase di. erences between the hot spots and the planets observed in HD 179949,. And, HD 189733, and tau Bootis, as well as their visibility modulation on the orbital period and seasonal time scales. The possible presence of cool spots associated with the planets in t Boo and HD 192263 cannot be explained by the present model. However, we speculate about the possibility that reconnection events in the corona may influence subphotospheric dynamo action in those stars producing localized photospheric ( and chromospheric) activity migrating in phase with their planets.