# Formation of short-period planets by disk migration

**Authors:** Daniel Carrera, Eric B. Ford, and Andre Izidoro

arXiv: 1903.02004 · 2019-04-17

## TL;DR

This study proposes that short-period planets form through Type-I migration and resonance locking in protoplanetary disks, successfully reproducing observed period distributions and highlighting the roles of migration and dynamical interactions.

## Contribution

The paper introduces a new model combining N-body simulations and Kepler observation modeling to explain the formation of short-period planets via resonance chains and disk migration.

## Key findings

- Resonance chains migrate inward together in simulations.
- Simulated period distribution matches Kepler observations between 1-2 R⊕.
- Fewer closely packed planets are produced than observed.

## Abstract

Protoplanetary disks are thought to be truncated at orbital periods of around 10 days. Therefore, origin of rocky short period planets with $P < 10$ days is a puzzle. We propose that many of these planets may form through the Type-I migration of planets locked into a chain of mutual mean motion resonances. We ran N-body simulations of planetary embryos embedded in a protoplanetary disk. The embryos experienced gravitational scatterings, collisions, disk torques, and dampening of orbital eccentricity and inclination. We then modelled Kepler observations of these planets using a forward model of both the transit probability and the detection efficiency of the Kepler pipeline. We found that planets become locked into long chains of mean motion resonances that migrate in unison. When the chain reaches the edge of the disk, the inner planets are pushed past the edge due to the disk torques acting on the planets farther out in the chain. Our simulated systems successfully reproduce the observed period distribution of short period Kepler planets between 1 and 2 $R_\oplus$. However, we obtain fewer closely packed short period planets than in the Kepler sample. Our results provide valuable insight into the planet formation process, and suggests that resonance locks, migration, and dynamical instabilities play important roles the the formation and evolution of close-in small exoplanets.

## Full text

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## Figures

19 figures with captions in the complete paper: https://tomesphere.com/paper/1903.02004/full.md

## References

53 references — full list in the complete paper: https://tomesphere.com/paper/1903.02004/full.md

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Source: https://tomesphere.com/paper/1903.02004