ExELS: an exoplanet legacy science proposal for the ESA Euclid mission I. Cold exoplanets

TL;DR

The ExELS project for the ESA Euclid mission aims to detect and characterize cold and free-floating exoplanets down to Earth mass using gravitational microlensing, significantly advancing understanding of planet formation.

Contribution

This paper presents the first detailed simulation of Euclid's microlensing survey, including PSF blending effects, to estimate exoplanet detection yields and optimize survey design.

Findings

Detects a few hundred cold exoplanets, including Earth and Mars-mass planets.

Demonstrates Euclid's capability to measure the cold exoplanet mass function.

Analyzes the impact of survey parameters on detection efficiency.

Abstract

Euclid is the second M-class mission of the ESA Cosmic Vision programme, with the principal science goal of studying dark energy. Euclid is also expected to undertake additional Legacy Science programmes. One proposal is the Exoplanet Euclid Legacy Survey (ExELS) which will be the first survey able to measure the abundance of exoplanets down to Earth mass for host separations from ~1AU out to the free-floating (unbound) regime. The cold and free-floating exoplanet regimes represent a crucial discovery space for testing planet formation theories. ExELS will use the gravitational microlensing technique and will detect 1000 microlensing events per month over 1.6 deg^2 of the Galactic bulge. We assess how many of these events will have detectable planetary signatures using a detailed multi-wavelength microlensing simulator (MABuLS) which incorporates the Besancon Galactic model with 3D extinction. MABuLS is the first theoretical simulation of microlensing to treat the effects of point spread function (PSF) blending self-consistently with the underlying Galactic model. We use MABuLS, together with current numerical models for the Euclid PSFs, to explore a number of designs and de-scope options for ExELS, including the exoplanet yield as a function of filter choice and slewing time, and the effect of systematic photometry errors. Using conservative extrapolations of current empirical exoplanet mass functions determined from ground-based microlensing and radial velocity surveys, ExELS can expect to detect a few hundred cold exoplanets around mainly G, K and M-type stellar hosts, including ~45 Earth-mass planets and ~6 Mars-mass planets for an observing programme totalling 10 months. ExELS will be capable of measuring the cold exoplanet mass function down to Earth mass or below, with orbital separations from ~1AU to the free-floating regime. (Abridged)