The Dynamical Evolution of the Asteroid Belt

TL;DR

This paper reviews the complex dynamical and collisional processes that have shaped the asteroid belt's current properties, emphasizing the interplay between planetary migrations, instabilities, and asteroid evolution over three major phases.

Contribution

It provides a comprehensive synthesis of proposed models for asteroid belt evolution, highlighting the importance of dynamical and collisional interactions across different evolutionary phases.

Findings

Asteroid belt's current properties result from multiple dynamical and collisional processes.

Giant planet migrations and instabilities played a crucial role in shaping the belt.

Size distribution helps constrain dynamical evolution models.

Abstract

The asteroid belt is the leftover of the original planetesimal population in the inner solar system. However, currently the asteroids have orbits with all possible values of eccentricities and inclinations compatible with long-term dynamical stability, whereas the initial planetesimal orbits should have been quasi-circular and almost co-planar. The total mass in the asteroid population is a small fraction of that existing primordially. Also, asteroids with different chemical/mineralogical properties are not ranked in an orderly manner with mean heliocentric distance as one could expect from the existence of a radial gradient of the temperature in the proto-planetary disk, but they are partially mixed. These properties show that the asteroid belt has been severely sculpted by one or a series of processes during its lifetime. This paper reviews the processes that have been proposed so far, discussing the properties that they explain and the problems that they are confronted with. Emphasis is paid to the interplay between the dynamical and the collisional evolution of the asteroid population, which allows the use of the size distribution to constrain the dynamical models. We divide the asteroid belt evolution into three phases. The first phase started during the lifetime of the gaseous proto-planetary disk, when the giant planets formed and presumably experienced large-scale migrations, and continued after the removal of the gas, during the build-up of the terrestrial planets. The second phase occurred after the removal of the gaseous proto-planetary disk and it became particularly lively for the asteroid belt when the giant planets suddenly changed their orbits, as a result of a mutual dynamical instability and the interaction with the trans-Neptunian planetesimal disk. The third phase covers the aftermath of the giant planet instability, until today.