Photospheric activity, rotation, and radial velocity variations of the planet-hosting star CoRoT-7

TL;DR

This study models the magnetic activity of CoRoT-7 to understand its impact on radial velocity measurements, confirming the planetary signals and revealing the influence of stellar surface differential rotation.

Contribution

It introduces a method to synthesize activity-induced RV variations from spot models, improving planetary detection accuracy around active stars.

Findings

Active regions are mainly at three migrating longitudes.

Differential rotation period range is 23.6 to 27.6 days.

The method confirms planetary signals with a false-alarm probability < 0.01%.

Abstract

The CoRoT satellite has recently discovered the transits of a telluric planet across the disc of a late-type magnetically active star dubbed CoRoT-7, while a second planet has been detected after filtering out the radial velocity (hereafter RV) variations due to stellar activity. We investigate the magnetic activity of CoRoT-7 and use the results for a better understanding of its impact on stellar RV variations. We derive the longitudinal distribution of active regions on CoRoT-7 from a maximum entropy spot model of the CoRoT light curve. Assuming that each active region consists of dark spots and bright faculae in a fixed proportion, we synthesize the expected RV variations. Active regions are mainly located at three active longitudes which appear to migrate at different rates, probably as a consequence of surface differential rotation, for which a lower limit of \Delta \Omega / \Omega = 0.058 \pm 0.017 is found. The synthesized activity-induced RV variations reproduce the amplitude of the observed RV curve and are used to study the impact of stellar activity on planetary detection. In spite of the non-simultaneous CoRoT and HARPS observations, our study confirms the validity of the method previously adopted to filter out RV variations induced by stellar activity. We find a false-alarm probability < 0.01 percent that the RV oscillations attributed to CoRoT-7b and CoRoT-7c are spurious effects of noise and activity. Additionally, our model suggests that other periodicities found in the observed RV curve of CoRoT-7 could be explained by active regions whose visibility is modulated by a differential stellar rotation with periods ranging from 23.6 to 27.6 days.