From Planetesimals to Dwarf Planets by Pebble Accretion

TL;DR

This study investigates how pebble accretion influences the size distribution of trans-Neptunian objects, especially dwarf planets, in the Kuiper Belt, revealing key environmental parameters and growth mechanisms involved.

Contribution

It demonstrates that pebble accretion selectively grows the most massive bodies in the Kuiper Belt, providing new insights into dwarf planet formation and the role of pebble dynamics.

Findings

Pebble accretion explains the size distribution of hot TNOs.

Massive bodies exceeding 10^-4 Earth masses likely become dwarf planets.

Environmental parameters like pebble size and turbulence are constrained.

Abstract

The size distribution of TNOs in the Kuiper Belt provides crucial insights into the formation and evolution of the outer Solar System. Recent observational surveys, including OSSOS++, have revealed that dynamically cold and hot TNO populations exhibit similar size distributions for dimmer objects ($H_r > 5$), which are consistent with planetesimal formation by streaming instability (SI). However, the hot population contains a significantly larger number of massive bodies, including several dwarf planets. In this study, we investigate the role of pebble accretion in shaping the size distribution of hot TNOs, after their formation in the primordial disk (PB) between 20 and 30 au and before these bodies were dynamically implanted into their current orbits by a migrating Neptune. We find that pebble accretion grows the most massive bodies only, consistent with the flattening of the distribution brightwards of $H_r=5$. All results point to a correlation (degeneracy) between the pebble aerodynamic size and the intensity of the gas motions. Nevertheless, accretion from an inward-drifting stream of pebbles is unlikely, as it puts extreme demands on the mass budget of pebbles. In particular, the masses of the cold classicals are too low to trigger pebble accretion. Accretion in an environment where pebbles are entrained, as believed to be the case in rings seen with ALMA, is preferable. Combining the constraints obtained from this study with ALMA imagery morphology fitting reveals a typical pebble aerodynamic size of $\tau_s \sim 10^{-2}$, a turbulent diffusivity parameter $\alpha_D\sim10^{-3}$, and a total accreted pebble mass of ${\sim}10\,m_\oplus$ in the primordial belt. Those TNOs formed through significant pebble accretion with masses exceeding ${\sim}10^{-4}\,m_\oplus$ are likely to satisfy the International Astronomical Union's ``round shape'' criterion for dwarf planets.