📝 SummarXiv

Abstract

Context: With no conclusive detection to date, the search for exomoons, satellites of planets orbiting other stars, remains a formidable challenge. Detecting these objects, compiling a population-level sample and constraining their occurrence will inform planet and moon formation models and shed light on moon habitability. Aims: Here, we demonstrate the possibility of a moon search based on astrometric time series data, repeated measurements of the position of a given planet relative to its host star. The perturbing influence of an orbiting moon induces a potentially detectable planetary reflex motion. Methods: Based on an analytical description of the astrometric signal amplitude, we place the expected signatures of putative moons around real exoplanets into context with our current and future astrometric measurement precision. Modelling the orbital perturbation as a function of time, we then simulate the detection process to obtain the first astrometric exomoon sensitivity curves. Results: The astrometric technique already allows for the detection and characterisation of favourable moons around giant exoplanets and brown dwarfs. On the basis of 12 epochs obtained with VLTI/GRAVITY, it is already today possible to infer the presence of a 0.14 $\mathrm{M}_\mathrm{Jup}$ satellite at a separation of 0.39 AU around AF Lep b. Future facilities offering better precision will refine our sensitivity in both moon mass and separation from the host planet by several orders of magnitude. Conclusions: The astrometric method of exomoon detection provides a promising avenue towards making the detection of these elusive worlds a reality and efficiently building a sample of confirmed objects. With a future facility that achieves an astrometric precision of 1 mas, probing for Earth-like moons within the habitable zone of a given star will become a realistic proposition.