Star-planet interaction and its impact on the stellar rotation
Thiago M. Santiago, Sarah G. A. Barbosa, Francisco J. Cavalcante, Daniel B. de Freitas
arXiv:2404.06958v1 Announce Type: new
Abstract: The stellar rotation has an essential role in modifying the structure of the star and, therefore, the way these different interplays arise. On the other hand, changes in orbits impact the star’s rotation and its evolution. The evolution of the star’s rotation accounts for the angular momentum exchange with the planet and follows the effects of the internal transport of angular momentum and metallicity. Several models in the literature have aimed to find a theoretical way to study these interactions between the planet’s orbital evolution and the star’s rotation. Our work is a promising attempt to investigate these interactions from a model based on a new statistical approach. To this end, we propose a “tidal interaction index” that carries all the parameters of the star-planet system that can affect the transport of angular momentum and, consequently, the evolution of stellar rotation. This index is similar to the “magnetic braking index” whose most successful value equals 3, which expresses the seminal Skumunich law. Our model is computed for masses of the host star less than the Kraft limit for three orbital-rotation period regimes and the semi-major axis less than 1 AU. We consider planets with masses between 0.4M$_{oplus}$ and 20M$_{rm J}$ with orbital periods between 0.3 and 225 days. We show that the tidal index $q$ segregated by stellar mass without wind magnetic braking during the main-sequence phase is strongly anti-correlated with planetary mass. Finally, we conclude that in cases where planets retain less than 84% of the total angular momentum within the system, the magnetic braking mechanism proves to be more effective than tidal interactions, irrespective of whether the planets’ angular momentum surpasses that of the host star.arXiv:2404.06958v1 Announce Type: new
Abstract: The stellar rotation has an essential role in modifying the structure of the star and, therefore, the way these different interplays arise. On the other hand, changes in orbits impact the star’s rotation and its evolution. The evolution of the star’s rotation accounts for the angular momentum exchange with the planet and follows the effects of the internal transport of angular momentum and metallicity. Several models in the literature have aimed to find a theoretical way to study these interactions between the planet’s orbital evolution and the star’s rotation. Our work is a promising attempt to investigate these interactions from a model based on a new statistical approach. To this end, we propose a “tidal interaction index” that carries all the parameters of the star-planet system that can affect the transport of angular momentum and, consequently, the evolution of stellar rotation. This index is similar to the “magnetic braking index” whose most successful value equals 3, which expresses the seminal Skumunich law. Our model is computed for masses of the host star less than the Kraft limit for three orbital-rotation period regimes and the semi-major axis less than 1 AU. We consider planets with masses between 0.4M$_{oplus}$ and 20M$_{rm J}$ with orbital periods between 0.3 and 225 days. We show that the tidal index $q$ segregated by stellar mass without wind magnetic braking during the main-sequence phase is strongly anti-correlated with planetary mass. Finally, we conclude that in cases where planets retain less than 84% of the total angular momentum within the system, the magnetic braking mechanism proves to be more effective than tidal interactions, irrespective of whether the planets’ angular momentum surpasses that of the host star.