Spectroscopic Characterization of LOFAR Radio-emitting M dwarfs

TL;DR

This study uses spectroscopic data to characterize radio-emitting M dwarfs, identifying potential star-planet interaction candidates and refining their properties to understand the origin of their radio emissions.

Contribution

It provides a comprehensive spectroscopic analysis of LOFAR radio-emitting M dwarfs, identifying strong candidates for star-planet interactions and refining their orbital and stellar parameters.

Findings

Identified GJ 625, GJ 1151, and LHS 2395 as single, quiescent stars suitable for RV follow-up.

Found stellar inclination distribution consistent with isotropy, showing no pole-on bias.

Refined orbital parameters of GJ 625 b and discovered GJ 3861 as a short-period spectroscopic binary.

Abstract

Recent observations with the LOw Frequency ARray (LOFAR) have revealed 19 nearby M dwarfs showing bright circularly polarised radio emission. One of the possible sources of such emission is through magnetic star-planet interactions (MSPI) with unseen close-in planets. We present initial results from a spectroscopic survey with the Habitable-zone Planet Finder (HPF) and NEID spectrographs designed to characterize this sample and further investigate the origin of the radio emission. We provide four new insights into the sample. I) We uniformly characterize the stellar properties, constraining their effective temperatures, surface gravities, metallicities, projected rotational velocities, rotation periods, stellar radii, and stellar inclinations where possible. Further, from a homogenous analysis of the HPF spectra, we infer their chromospheric activity and spectroscopic multiplicity states. From this, we identify GJ 625, GJ 1151, and LHS 2395 as single, quiescent stars amenable to precise RV follow-up, making them strong MSPI candidates. II) We show that the distribution of stellar inclinations are compatible with an isotropic distribution, providing no evidence for a preference to pole-on configurations. III) We refine the radial velocity solution for GJ 625 b, the only currently known close-in planet in the sample, reducing the uncertainty in its orbital period by a factor of three, to facilitate future phase-dependent radio analysis. IV) Finally, we identify GJ 3861 as a spectroscopic binary with an orbital period of $P=14.841181_{-0.00010}^{+0.00011}$ d, making it the only confirmed binary with a relatively short orbit in the sample, where we surmise the radio emission is likely related to magnetospheric interactions between the two stars. These results advance our understanding of radio-emitting M dwarfs and establish an observational foundation for identifying MSPI.