Predictions of planet detections with near infrared radial velocities in the up-coming SPIRou Legacy Survey-Planet Search

TL;DR

This study uses Monte Carlo simulations to predict the number and types of exoplanets that the upcoming SPIRou near-infrared spectro-polarimeter will detect around nearby M dwarfs during its 3-5 year survey, considering stellar activity and planetary occurrence rates.

Contribution

It provides the first detailed prediction of exoplanet yields for the SPIRou Legacy Survey-Planet Search using current models and simulations, guiding future observational strategies.

Findings

Expected to detect approximately 85 planets, including habitable and Earth-like planets.

Predicted detection of about 20 habitable zone planets and 8 Earth-like planets.

Provides constraints on planet occurrence rates around mid-to-late M dwarfs.

Abstract

The SPIRou near infrared spectro-polarimeter is destined to begin science operations at the Canada-France-Hawaii Telescope in mid-2018. One of the instrument's primary science goals is to discover the closest exoplanets to the Solar System by conducting a 3-5 year long radial velocity survey of nearby M dwarfs at an expected precision of $\sim 1$ m s$^{-1}$; the SPIRou Legacy Survey-Planet Search (SLS-PS). In this study we conduct a detailed Monte-Carlo simulation of the SLS-PS using our current understanding of the occurrence rate of M dwarf planetary systems and physical models of stellar activity. From simultaneous modelling of planetary signals and activity, we predict the population of planets detected in the SLS-PS. With our fiducial survey strategy and expected instrument performance over a nominal survey length of $\sim 3$ years, we expect SPIRou to detect $85.3^{+29.3}_{-12.4}$ planets including $20.0^{+16.8}_{-7.2}$ habitable zone planets and $8.1^{+7.6}_{-3.2}$ Earth-like planets from a sample of 100 M1-M8.5 dwarfs out to 11 pc. By studying mid-to-late M dwarfs previously inaccessible to existing optical velocimeters, SPIRou will put meaningful constraints on the occurrence rate of planets around those stars including the value of $\eta_{\oplus}$ at an expected level of precision of $\lesssim 45$%. We also predict a subset of $46.7^{+16.0}_{-6.0}$ planets may be accessible with dedicated high-contrast imagers on the next generation of ELTs including $4.9^{+4.7}_{-2.0}$ potentially imagable Earth-like planets. Lastly, we compare the results of our fiducial survey strategy to other foreseeable survey versions to quantify which strategy is optimized to reach the SLS-PS science goals. The results of our simulations are made available to the community on github.