The Scorpion Planet Survey: Wide-Orbit Giant Planets Around Young A-type Stars

TL;DR

This survey used advanced imaging to study 84 young A-type stars, finding a low but significant frequency of wide-orbit giant planets, supporting core accretion as their formation process.

Contribution

First direct imaging survey of a large sample of young A-stars constraining the frequency and distribution of wide-orbit giant planets.

Findings

Giant planet frequency decreases with increasing orbital separation.

Measured 10-2% frequency for 30-100 au, with upper limits up to 45-8%.

Results support core accretion as the dominant formation mechanism.

Abstract

The first directly imaged exoplanets indicated that wide-orbit giant planets could be more common around A-type stars. However, the relatively small number of nearby A-stars has limited the precision of exoplanet demographics studies to $\gtrsim$10%. We aim to constrain the frequency of wide-orbit giant planets around A-stars using the VLT/SPHERE extreme adaptive optics system, which enables targeting $\gtrsim$100 A-stars between 100$-$200 pc. We present the results of a survey of 84 A-stars within the nearby $\sim$5$-$17 Myr-old Sco OB2 association. The survey detected three companions$-$one of which is a new discovery (HIP75056Ab), whereas the other two (HD 95086b and HIP65426b) are now-known planets that were included without a priori knowledge of their existence. We assessed the image sensitivity and observational biases with injection and recovery tests combined with Monte Carlo simulations to place constraints on the underlying demographics. We measure a decreasing frequency of giant planets with increasing separation, with measured values falling between 10$-$2% for separations of 30$-$100 au, and 95% confidence-level (CL) upper limits of $\lesssim$45$-$8% for planets on 30$-$100 au orbits, and $\lesssim$5% between 200$-$500 au. These values are in excellent agreement with recent surveys of A-stars in the solar neighborhood$-$supporting findings that giant planets at $\lesssim$100 au are more frequent around A-stars than around solar-type hosts. Finally, the relatively low occurrence rate of super-Jupiters on wide orbits, the positive correlation with stellar mass, and the inverse correlation with orbital separation are consistent with core accretion being their dominant formation mechanism.