Mars’ Formation Can Constrain the Primordial Orbits of the Gas Giants

• Published in: Astrophysical journal. Letters Vol. 910; no. 2; p. L16
• Main Authors: Woo, Jason Man Yin, Stadel, Joachim, Grimm, Simon, Brasser, Ramon
• Format: Journal Article
• Language: English
• Published: Austin IOP Publishing 01.04.2021
• Subjects: Accretion; Circular orbits; Deposition; Eccentric orbits; Gas giant planets; Jupiter; Mars; Mercury; Mercury (planet); Orbital stability; Planet formation; Saturn; Solar system; Venus
• ISSN: 2041-8205; 2041-8213
• DOI: 10.3847/2041-8213/abed56

Abstract Recent high-precision meteoritic data infers that Mars finished its accretion rapidly within 10 Myr of the beginning of the Solar System and had an accretion zone that did not entirely overlap with the Earth’s. Here we present a detailed study of the accretion zone of planetary embryos from high-resolution simulations of planetesimals in a disk. We found that all simulations with Jupiter and Saturn on their current eccentric orbits (EJS) result in a similar accretion zone between fast-forming Mars and Earth-region embryos. Assuming more circular orbits for Jupiter and Saturn (CJS), on the other hand, has a significantly higher chance of forming Mars with an accretion zone not entirely dominated by Earth and Venus-region embryos; however, CJS in general forms Mars slower than in EJS. By further quantifying the degree of overlap between accretion zones of embryos in different regions with the average overlap coefficient (OVL), we found that the OVL of CJS shows a better match with the OVL from a chondritic isotopic mixing model of Earth and Mars, which indicates that the giant planets are likely to have resided on more circular orbits during gas disk dissipation than they do today, matching their suggested pre-instability orbits. More samples, including those from Mercury and Venus, could potentially confirm this hypothesis.