Analytical Solutions for Planet-Scattering Small Bodies
Abstract
Gravitational scattering of small bodies (planetesimals) by a planet remains a fundamental problem in celestial mechanics. It is traditionally modeled within the circular restricted three-body problem (CR3BP), where individual particle trajectories are obtained via numerical integrations. Here, we use \"Opik's close-encounter framework to study the random walk of the orbital energy x for an ensemble of test particles on planet-crossing orbits. We show that the evolution of each particle's orbital elements (a, e, i) is fully encapsulated by the 3D rotation of the relative velocity vector U∞, whose magnitude remains constant. Consequently, the system can be reduced to two degrees of freedom. By averaging over all possible flyby geometries, we derive explicit expressions for the drift and diffusion coefficients of x. We then solve the resulting Fokker--Planck equation to obtain a closed-form solution for the time evolution of the particle distribution. A characteristic scattering timescale naturally emerges, scaling as (Pp/Mp2)/500, where Pp is the planet's orbital period and Mp its mass ratio to the central star. The typical ejection speed of small bodies by a planet is estimated to be 3 vp Mp1/3, where vp is the planet's orbital speed. Our analytical solution constitutes a universal law applicable to both the Solar System and exoplanetary systems, providing a computationally efficient alternative to costly N-body simulations for studying the orbital distributions and ejection of planetesimals and planets (e.g., Kuiper Belt, Oort Cloud, debris disks, interstellar objects, and free-floating planets).
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.