Collisional evolution of dust aggregates. From compaction to catastrophic destruction

TL;DR

This paper investigates the microphysics of dust aggregate collisions in astrophysical environments, exploring how parameters like impact energy and initial compactness influence outcomes, and provides a collision recipe for predicting aggregate evolution.

Contribution

It introduces a comprehensive molecular dynamics model for dust collisions and develops a simple, tabulated collision recipe accounting for various physical parameters.

Findings

Impact parameter influences aggregate elongation and internal structure.

Collision outcomes depend on impact energy and initial compactness.

A tabulated collision recipe summarizes the results across parameter space.

Abstract

The coagulation of dust aggregates occurs in various astrophysical environments. Each one is characterized by different conditions that influence the growth, e.g. relative velocities, composition, and size of the smallest constituents (monomers). Here we study the microphysics of collisions of dust aggregates in a four-dimensional parameter space. The parameters are the collision energy, the initial compactness of agglomerates, the mass ratio of collision partners, and the impact parameter. For this purpose we employ a state of the art molecular dynamics type of model that has been extensively and successfully tested against laboratory experiments. It simulates the motion of individual monomers interacting dynamically via van der Waals surface forces. The structure of aggregates is quantified by the filling factor that provides information about the internal structure, the packing density of monomers, and the projected surface area of aggregates. Our results show the importance of the impact parameter that causes formation of elongated particles, due to tensile forces acting in offset collisions. We also describe in detail the internal structure of the resulting aggregates. Our findings are summarized in the form of a simple collision recipe. The recipe specifies the outcome of a collision, averaged over the impact parameter. It is provided in tabular form for a range of physical parameters such as impact energy and pre-collision filling factor. The dependence on the mass ratio of impactor and target is taken into account by providing both a local and a global branch of the recipe.