A low-mass sub-Neptune planet transiting the bright active star HD 73344

TL;DR

This study confirms a sub-Neptune transiting planet around the active star HD 73344, using high-cadence RV data and multi-instrument observations, revealing a potential second nontransiting planet and emphasizing the challenges posed by stellar activity.

Contribution

The paper introduces a novel high-cadence RV observing strategy combined with Gaussian process modeling to better constrain planetary parameters around active stars.

Findings

Confirmed a transiting sub-Neptune planet around HD 73344.

Detected a periodic RV signal indicating a possible second nontransiting planet.

Highlighted the impact of stellar activity on precise mass measurements.

Abstract

Context. Planets with radii of between 2-4 RE closely orbiting solar-type stars are of significant importance for studying the transition from rocky to giant planets. Aims. Our goal is to determine the mass of a transiting planet around the very bright F6 star HD 73344 . This star exhibits high activity and has a rotation period that is close to the orbital period of the planet. Methods. The transiting planet, initially a K2 candidate, is confirmed through TESS observations . We refined its parameters and rule out a false positive with Spitzer observations. We analyzed high-precision RV data from the SOPHIE and HIRES spectrographs. We conducted separate and joint analyses using the PASTIS software. We used a novel observing strategy, targeting the star at high cadence for two consecutive nights with SOPHIE to understand the short-term stellar variability. We modeled stellar noise with two Gaussian processes. Results. High-cadence RV observations provide better constraints on stellar variability and precise orbital parameters for the transiting planet. The derived mean density suggests a sub-Neptune-type composition, but uncertainties in the planet's mass prevent a detailed characterization. In addition, we find a periodic signal in the RV data that we attribute to the signature of a nontransiting exoplanet, without totally excluding the possibility of a nonplanetary origin. Dynamical analyses confirm the stability of the two-planet system and provide constraints on the inclination of the candidate planet; these findings favor a near-coplanar system. Conclusions. While the transiting planet orbits the bright star at a short period, stellar activity prevented us from precise mass measurements. Long-term RV tracking of this planet could improve this measurement, as well as our understanding of the activity of the host star.