Do anomalously-dense hot Jupiters orbit stealth binary stars?

TL;DR

This study investigates whether undetected binary star companions can cause overestimation of hot Jupiter densities by diluting transit and radial velocity signals, using cross-checked stellar radii measurements from WASP survey data.

Contribution

It identifies candidate stealth binary systems among WASP hot Jupiters and quantifies how their densities are affected by undetected stellar companions.

Findings

Eight systems with larger radiometric stellar radii identified

Stealth binaries can cause planetary density overestimation by a factor of 1.3

Methods to detect and account for undetected stellar companions proposed

Abstract

The Wide Angle Search for Planets (WASP) survey used transit photometry to discover nearly 200 gas-giant exoplanets and derive their planetary and stellar parameters. Reliable determination of the planetary density depends on accurate measurement of the planet's radius, obtained from the transit depth and photodynamical determination of the stellar radius. The stellar density, and hence the stellar radius are typically determined in a model-independent way from the star's reflex orbital acceleration and the transit profile. Additional flux coming from the system due to a bright, undetected stellar binary companion can, however, potentially dilute the transit curve and radial velocity signal, leading to under-estimation of the planet's mass and radius, and to overestimation of the planet's density. In this study, we cross-check the published radii of all the WASP planet host stars, determined from their transit profiles and radial-velocity curves, against radiometric measurements of stellar radii derived from their angular diameters (via the Infrared Flux method) and trigonometric parallaxes. We identify eight systems showing radiometric stellar radii significantly greater than their published photodynamical values: WASPs 20, 85, 86, 103, 105, 129, 144 and 171. We investigate these systems in more detail to establish plausible ranges of angular and radial-velocity separations within which such "stealth binaries" could evade detection, and deduce their likely orbital periods, mass ratios, and flux ratios. After accounting for the dilution of transit depth and radial velocity amplitude, we find that on average, the planetary densities for the identified stealth binary systems should be reduced by a factor of 1.3.