The evolution of exocomets and their source populations

TL;DR

This review summarizes current understanding of exocomet evolution, source reservoirs, dynamical delivery, physical changes, and effects of stellar evolution, highlighting gaps in knowledge due to observational limitations.

Contribution

It provides a comprehensive overview of exocomet evolution, source populations, and stellar influences, integrating recent mission data and theoretical insights.

Findings

Active cometary phase is transient for small bodies.

Dynamical channels can deliver comets to close orbits.

Reservoirs are depleted by dynamical and collisional processes.

Abstract

We review the current state of knowledge of the long-term evolution of the small bodies that give rise to comets and exocomets, as well as their reservoirs. The active cometary phase is only transitory, and bodies that become comets pass from a source population, such as the Kuiper Belt, Oort Cloud or their extra-solar analogues, through the active cometary phase, to eventual dormancy or destruction. We discuss dynamical delivery channels that can move comets from their source reservoirs to orbits with small periapsides, and the depletion of these reservoirs by dynamical and collisional means. We also discuss the physical evolution of cometary nuclei, especially in light of recent advances from missions to Solar System comets such as Rosetta's visit to 67P. We then describe our current knowledge of interstellar objects, which can originate from the same source regions as exocomets but be amenable to detailed study when they enter the Solar System. We include a summary of stellar winds emanating from different types of stars, which become increasingly strong once stars leave the Main Sequence. This is followed by a description of how small bodies are affected by stellar evolution, and the range of comet-like phenomena observed towards white dwarf stars. Overall, while we have an increasingly good picture of the physical and dynamical evolution of Solar System comets, a number of large gaps remain in our knowledge of the physics of exocomets, related to our inability to directly probe these bodies and many of the planets that might be affecting their orbits.