# Collisional formation of massive exomoons of super-terrestrial   exoplanets

**Authors:** Uri Malamud, Hagai B. Perets, Christoph Schaefer, Christoph Burger

arXiv: 1904.12854 · 2020-01-29

## TL;DR

This study uses simulations to explore how giant impacts could form massive exomoons around super-terrestrial planets, finding that such moons are rare but potentially detectable with future technology.

## Contribution

It provides the first detailed simulation-based analysis of exomoon formation via giant impacts, highlighting the rarity and properties of such moons.

## Key findings

- Exomoons can form through graze&capture scenarios, but are rare.
- Most collisions produce circumplanetary discs that can lead to exomoons.
- Massive, iron-rich exomoons beyond the synchronous radius are likely to be stable.

## Abstract

Exomoons orbiting terrestrial or super-terrestrial exoplanets have not yet been discovered; their possible existence and properties are therefore still an unresolved question. Here we explore the collisional formation of exomoons through giant planetary impacts. We make use of smooth particle hydrodynamical (SPH) collision simulations and survey a large phase-space of terrestrial/super-terrestrial planetary collisions. We characterize the properties of such collisions, finding one rare case in which an exomoon forms through a graze&capture scenario, in addition to a few graze&merge or hit&run scenarios. Typically however, our collisions form massive circumplanetary discs, for which we use follow-up N-body simulations in order to derive lower-limit mass estimates for the ensuing exomoons. We investigate the mass, long-term tidal-stability, composition and origin of material in both the discs and the exomoons. Our giant-impact models often generate relatively iron-rich moons, that form beyond the synchronous radius of the planet, and would thus tidally evolve outward with stable orbits, rather than be destroyed. Our results suggest that it is extremely difficult to collisionally form currently-detectable exomoons orbiting super-terrestrial planets, through single giant impacts. It might be possible to form massive, detectable exomoons through several mergers of smaller exomoons, formed by multiple impacts, however more studies are required in order to reach a conclusion. Given the current observational initiatives, the search should focus primarily on more massive planet categories. However, about a quarter of the exomoons predicted by our models are approximately Mercury-mass or more, and are much more likely to be detectable given a factor 2 improvement in the detection capability of future instruments, providing further motivation for their development.

## Full text

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## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1904.12854/full.md

## References

89 references — full list in the complete paper: https://tomesphere.com/paper/1904.12854/full.md

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Source: https://tomesphere.com/paper/1904.12854