Multiplicity of stars with planets in the solar neighbourhood

TL;DR

This study investigates how stellar multiplicity affects exoplanet presence and properties, revealing that planets in multiple star systems tend to have higher eccentricities and closer orbits, with some statistical significance.

Contribution

It provides a comprehensive analysis of exoplanets in multiple star systems using Gaia DR3 data, identifying new companions and comparing planetary characteristics with single star systems.

Findings

Planets in multiple systems tend to have higher eccentricities.

High-mass planets are more often found in closer orbits in multiple systems.

Statistical significance at 2σ level for some differences.

Abstract

- Aims: We intended to quantify the impact of stellar multiplicity on the presence and properties of exoplanets. - Methods: We investigated all exoplanet host stars at less than 100 pc using the latest astrometric data from Gaia DR3 and advanced statistical methodologies. We complemented our search for common proper motion and parallax companions with data from the Washington Double Star catalogue and the literature. After excluding a number of systems based on radial velocity data, and membership in clusters and open associations, or with resolved ultracool companions, we kept 215 exoplanet host stars in 212 multiple-star systems. - Results: We found 17 new companions in the systems of 15 known exoplanet host stars, measured precise angular and projected physical separations and position angles for 236 pairs of stars, compiled key parameters for 276 planets in multiple systems, and established a comparison sample comprising 687 single stars with exoplanets. With all of this, we statistically analysed a series of hypothesis regarding planets in multiple stellar systems. Although they are only statistically significant at a 2{\sigma} level, our analysis pointed to several interesting results on the comparison in the mean number of planets in multiple versus single stellar systems and the tendency of high mass planets to be located in closer orbits in multiple systems. We confirm that planets in multiple systems tend to have orbits with larger eccentricities than those in single systems. In particular, we found a significant (> 4{\sigma}) preference for planets to exhibit high orbital eccentricities at small ratios between star-star projected physical separations and star-planet semi-major axes.