Runaway Growth During Planet Formation: Explaining the Size Distribution of Large Kuiper Belt Objects

TL;DR

This paper models runaway growth during planet formation, explaining the size distribution of large Kuiper Belt Objects and showing that their current mass is likely primordial, based on analytic and simulation results.

Contribution

It provides a new analytic framework for understanding runaway growth and the resulting size distribution of large protoplanets, validated by coagulation simulations.

Findings

Runaway growth leads to a size distribution N(>R) ∝ R^{-3}.

The Kuiper Belt's observed size distribution matches the model predictions.

The total mass in large Kuiper Belt Objects is likely primordial and not significantly depleted.

Abstract

Runway growth is an important stage in planet formation during which large protoplanets form, while most of the initial mass remains in small planetesimals. The amount of mass converted into large protoplanets and their resulting size distribution are not well understood. Here, we use analytic work, that we confirm by coagulation simulations, to describe runaway growth and the corresponding evolution of the velocity dispersion. We find that runaway growth proceeds as follows: Initially all the mass resides in small planetesimals, with mass surface density \sigma, and large protoplanets start to form by accreting small planetesimals. This growth continues until growth by merging large protoplanets becomes comparable to growth by planetesimal accretion. This condition sets in when \Sigma/\sigma ~\alpha^{3/4} ~ 10^{-3}, where \Sigma is the mass surface density in protoplanets in a given logarithmic mass interval and \alpha is the ratio of the size of a body to its Hill radius. From then on, protoplanetary growth and the evolution of the velocity dispersion become self-similar and \Sigma remains roughly constant, since an increase in \Sigma by accretion of small planetesimals is balanced by a decrease due to merging with large protoplanets. We show that this growth leads to a protoplanet size distribution given by N(>R) \propto R^{-3} where N(>R) is the number of objects with radii greater than R (i.e., a differential power-law index of 4). We apply our results to the Kuiper Belt, which is a relic of runaway growth. Our results successfully match the observed Kuiper belt size distribution, they illuminate the physical processes that shaped it and explain the total mass that is present in large Kuiper belt objects (KBOs) today. This work suggests that the current mass in large KBOs is primordial and that it has not been significantly depleted. Abridged