Litcius/Paper detail

Transit origami: a method to coherently fold exomoon transits in time series photometry

David Kipping

2021Monthly Notices of the Royal Astronomical Society15 citationsDOIOpen Access PDF

Abstract

ABSTRACT One of the simplest ways to identify an exoplanetary transit is to phase fold a photometric time series upon a trial period – leading to a coherent stack when using the correct value. Such phase-folded transits have become a standard data visualization in modern transit discovery papers. There is no analogous folding mechanism for exomoons, which would have to represent some kind of double fold: once for the planet and then another for the moon. Folding with the planet term only, a moon imparts a small decrease in the surrounding out-of-transit averaged intensity, but its incoherent nature makes it far less convincing than the crisp stacks familiar to exoplanet hunters. Here, a new approach is introduced that can be used to achieve the transit origami needed to double fold an exomoon, in the case where a planet exhibits transit timing variations (TTVs). This double fold has just one unknown parameter, the satellite-to-planet mass ratio, and thus a simple one-dimensional grid search can be used to rapidly identify power associated with candidate exomoons. The technique is demonstrated on simulated light curves, exploring the breakdown limits of close-in and/or inclined satellites. As an example, the method is deployed on Kepler-973b, a warm mini-Neptune exhibiting an 8-min TTV, where the possibility that the TTVs are caused by a single exomoon is broadly excluded, with upper limits probing down to a Ganymede-sized moon.

Topics & Concepts

PhysicsExoplanetPlanetPhotometry (optics)Transit (satellite)AstronomyLight curveAstrophysicsNeptuneStarsPolitical sciencePublic transportLawStellar, planetary, and galactic studiesAstrophysics and Star Formation StudiesAstronomy and Astrophysical Research