The Direct Detectability of Giant Exoplanets in the Optical

Abstract

Motivated by the possibility that a coronagraph will be put on WFIRST/AFTA, we explore the direct detectability of extrasolar giant planets (EGPs) in the optical. We quantify a planet's detectability by the fraction of its orbit for which it is in an observable configuration (fobs). Using a suite of Monte Carlo experiments, we study the dependence of fobs upon the inner working angle (IWA) and minimum achievable contrast (Cmin) of the direct-imaging observatory; the planet's phase function, geometric albedo, single-scattering albedo, radius, and distance from Earth; and the semi-major axis distribution of EGPs. We calculate phase functions for a given geometric or single-scattering albedo, assuming various scattering mechanisms. We find that the Lambertian phase function can predict significantly larger fobs's with respect to the more realistic Rayleigh phase function. For observations made with WFIRST/AFTA's baseline capabilities (Cmin10-9, IWA0.2''), Jupiter-like planets orbiting stars within 10, 30, and 50 parsecs of Earth have volume-averaged observability fractions of 12%, 3%, and 0.5%, respectively. At 10 parsecs, such observations yield fobs>1\% for low- to modest-eccentricity planets with semi-major axes in the range 2 - 10 AU. If Cmin=10-10, this range extends to 35 AU. We find that, in all but the most optimistic configurations, the probability for detection in a blind search is low (<\,5\%). However, with orbital parameter constraints from long-term radial-velocity campaigns and Gaia astrometry, the tools we develop in this work can be used to determine both the most promising systems to target and when to observe them.