ORBITAL STABILITY OF MULTI-PLANET SYSTEMS: BEHAVIOR AT HIGH MASSES

• Published in: The Astrophysical journal Vol. 823; no. 2; p. 118
• Main Authors: Morrison, Sarah J., Kratter, Kaitlin M.
• Format: Journal Article
• Language: English
• Published: United States The American Astronomical Society 01.06.2016
• Subjects: ASTROPHYSICS, COSMOLOGY AND ASTRONOMY; celestial mechanics; chaos; EVOLUTION; Extrapolation; Extrasolar planets; INSTABILITY; INTERACTIONS; MASS; MECHANICS; Orbital mechanics; Orbital stability; ORBITS; planet-disk interactions; Planetary evolution; Planetary systems; PLANETS; planets and satellites: dynamical evolution and stability; RESONANCE; SATELLITES; STABILITY; STARS
• ISSN: 0004-637X; 1538-4357
• DOI: 10.3847/0004-637X/823/2/118

ABSTRACT In the coming years, high-contrast imaging surveys are expected to reveal the characteristics of the population of wide-orbit, massive, exoplanets. To date, a handful of wide planetary mass companions are known, but only one such multi-planet system has been discovered: HR 8799. For low mass planetary systems, multi-planet interactions play an important role in setting system architecture. In this paper, we explore the stability of these high mass, multi-planet systems. While empirical relationships exist that predict how system stability scales with planet spacing at low masses, we show that extrapolating to super-Jupiter masses can lead to up to an order of magnitude overestimate of stability for massive, tightly packed systems. We show that at both low and high planet masses, overlapping mean-motion resonances trigger chaotic orbital evolution, which leads to system instability. We attribute some of the difference in behavior as a function of mass to the increasing importance of second order resonances at high planet-star mass ratios. We use our tailored high mass planet results to estimate the maximum number of planets that might reside in double component debris disk systems, whose gaps may indicate the presence of massive bodies.