# Spinning up planetary bodies by pebble accretion

**Authors:** R.G. Visser, C.W. Ormel, C. Dominik, S. Ida

arXiv: 1907.04368 · 2019-09-25

## TL;DR

This paper investigates how pebble accretion, involving small particles and gas dynamics, can naturally produce the prograde spins of planetary bodies, offering an alternative to the giant impact model.

## Contribution

It demonstrates that pebble accretion can generate significant net angular momentum, potentially explaining planetary spins without collisions.

## Key findings

- Pebble accretion can impart substantial angular momentum to planetary bodies.
- The effect varies with disk conditions and pebble properties.
- In some scenarios, pebble accretion exceeds the current planetary spin.

## Abstract

Most major planetary bodies in the solar system rotate in the same direction as their orbital motion: their spin is prograde. Theoretical studies to explain the direction as well as the magnitude of the spin vector have had mixed success. When the accreting building blocks are $\sim$ km-size planetesimals -- as predicted by the classical model -- the accretion process is so symmetric that it cancels out prograde with retrograde spin contributions, rendering the net spin minute. For this reason, the currently-favored model for the origin of planetary rotation is the giant impact model, in which a single collision suffices to deliver a spin, which magnitude is close to the breakup rotation rate. However, the giant impact model does not naturally explain the preference for prograde spin. Similarly, an increasing number of spin-vector measurement of asteroids also shows that the spin vector of large (primordial) asteroids is not isotropic. Here, we re-assess the viability of smaller particles to bestow planetary bodies with a net spin, focusing on the pebble accretion model in which gas drag and gravity join forces to accrete small particles at a large cross section. Similar to the classical calculation for planetesimals, we integrate the pebble equation of motion and measure the angular momentum transfer at impact. We consider a variety of disk conditions and pebble properties and conduct our calculations in the limits of 2D (planar) and 3D (homogeneous) pebble distributions. We find that in certain regions of the parameter space the angular momentum transfer is significant, much larger than with planetesimals and on par with or exceeding the current spin of planetary bodies.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1907.04368/full.md

## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1907.04368/full.md

## References

51 references — full list in the complete paper: https://tomesphere.com/paper/1907.04368/full.md

---
Source: https://tomesphere.com/paper/1907.04368