Connecting planet formation and astrochemistry: C/O and N/O of warm giant planets and Jupiter-analogs

TL;DR

This study models the chemical evolution of warm giant planets' atmospheres, linking their C/O and N/O ratios to their formation locations and disk properties, providing insights into planet formation processes and Jupiter's origin.

Contribution

It introduces a population synthesis model for warm Jupiters that predicts atmospheric C/O and N/O ratios based on astrochemical evolution, connecting formation location with observed chemical signatures.

Findings

Most synthetic planets follow the mass-metallicity relation.

High-metallicity disks produce more chemical diversity.

Jupiter's composition suggests formation beyond 5 AU.

Abstract

(Abridged) The chemical composition of planetary atmospheres has long been thought to store information regarding where and when a planet accretes its material. Predicting this chemical composition theoretically is a crucial step in linking observational studies to the underlying physics that govern planet formation. As a follow-up to a study of hot Jupiters in our previous work, we present a population of warm Jupiters (semi-major axis between 0.5-4 AU) extracted from the same planetesimal formation population synthesis model as used in our previous work. We compute the astrochemical evolution of the protoplanetary disks included in this population to predict the carbon-to-oxygen (C/O) and nitrogen-to-oxygen (N/O) ratio evolution of the disk gas, ice, and refractory sources, the accretion of which greatly impacts the resulting C/O and N/O in the atmosphere of giant planets. We confirm that the main sequence (between accreted solid mass and atmospheric C/O) we found previously is largely reproduced by the presented population of synthetic warm Jupiters. And as a result, the majority of the population fall along the empirically derived mass-metallicity relation when the natal disk has solar or lower metallicity. Planets forming from disks with high metallicity ([Fe/H] $>$ 0.1) result in more scatter in chemical properties which could explain some of the scatter found in the mass-metallicity relation. Combining predicted C/O and N/O ratios shows that Jupiter does not fall among our population of synthetic planets, suggesting that it likely did not form in the inner 5 AU of the solar system before proceeding into a Grand Tack. This result is consistent with recent analysis of the chemical composition of Jupiter's atmosphere which suggests that it accreted most of its heavy element abundance farther than tens of AU away from the Sun.