A bimodal correlation between host star chromospheric emission and the surface gravity of hot Jupiters

TL;DR

This study reveals a bimodal correlation between stellar chromospheric activity and hot Jupiter surface gravity, supporting a model where planetary evaporation influences stellar emission measurements.

Contribution

It introduces a two-regression model explaining the correlation, linking planetary evaporation effects to observed stellar activity indices, and refines understanding of star-planet interactions.

Findings

Data best fit by a two-linear-regression model

Supports the planetary evaporation condensation hypothesis

Interprets the Vaughan-Preston gap in this context

Abstract

The chromospheric activity index logR'HK of stars hosting transiting hot Jupiters appears to be correlated with the planets' surface gravity. One of the possible explanations is based on the presence of condensations of planetary evaporated material located in a circumstellar cloud that absorbs the CaII H&K and MgII h&k resonance line emission flux, used to measure chromospheric activity. A larger column density in the condensations, or equivalently a stronger absorption in the chromospheric lines, is obtained when the evaporation rate of the planet is larger, which occurs for a lower gravity of the planet. We analyze here a sample of stars hosting transiting hot Jupiters tuned in order to minimize systematic effects (e.g., interstellar medium absorption). Using a mixture model, we find that the data are best fit by a two-linear-regression model. We interpret this result in terms of the Vaughan-Preston gap. We use a Monte Carlo approach to best take into account the uncertainties, finding that the two intercepts fit the observed peaks of the distribution of logR'HK for main-sequence solar-like stars. We also find that the intercepts are correlated with the slopes, as predicted by the model based on the condensations of planetary evaporated material. Our findings bring further support to this model, although we cannot firmly exclude different explanations. A precise determination of the slopes of the two linear components would allow one to estimate the average effective stellar flux powering planetary evaporation, which can then be used for theoretical population and evolution studies of close-in planets.