The hot Jupiter of the magnetically-active weak-line T Tauri star V830 Tau

TL;DR

This study confirms the existence of a close-in giant planet around the magnetically active T Tauri star V830 Tau, using spectropolarimetric data and advanced modeling to distinguish planetary signals from stellar activity.

Contribution

It introduces a successful method for detecting exoplanets around active young stars by modeling activity jitter with Gaussian-process regression.

Findings

Confirmed the V830 Tau b planet with refined orbital parameters.

Demonstrated the effectiveness of Gaussian-process regression in RV data analysis.

Provided insights into star-planet formation around young stellar objects.

Abstract

We report results of an extended spectropolarimetric and photometric monitoring of the weak-line T Tauri star V830 Tau and its recently-detected newborn close-in giant planet. Our observations, carried out within the MaTYSSE programme, were spread over 91d, and involved the ESPaDOnS and Narval spectropolarimeters linked to the 3.6m Canada-France-Hawaii, the 2m Bernard Lyot and the 8-m Gemini-North Telescopes. Using Zeeman-Doppler Imaging, we characterize the surface brightness distributions, magnetic topologies and surface differential rotation of V830 Tau at the time of our observations, and demonstrate that both distributions evolve with time beyond what is expected from differential rotation. We also report that near the end of our observations, V830 Tau triggered one major flare and two weaker precursors, showing up as enhanced red-shifted emission in multiple spectral activity proxies. With 3 different filtering techniques, we model the radial velocity (RV) activity jitter (of semi-amplitude 1.2km/s) that V830 Tau generates, successfully retrieve the 68m/s RV planet signal hiding behind the jitter, further confirm the existence of V830 Tau b and better characterize its orbital parameters. We find that the method based on Gaussian-process regression performs best thanks to its higher ability at modelling not only the activity jitter, but also its temporal evolution over the course of our observations, and succeeds at reproducing our RV data down to a rms precision of 35m/s. Our result provides new observational constraints on scenarios of star / planet formation and demonstrates the scientific potential of large-scale searches for close-in giant planets around T Tauri stars.