# Inefficient volatile loss from the Moon-forming disk: reconciling the   giant impact hypothesis and a wet Moon

**Authors:** Miki Nakajima, David J. Stevenson

arXiv: 1812.10502 · 2018-12-31

## TL;DR

This study models the Moon-forming disk's thermal structure to assess volatile loss, finding that hydrogen escape was limited and the Moon could retain more water than previously thought, challenging existing depletion explanations.

## Contribution

It demonstrates that hydrogen escape from the Moon-forming disk was diffusion-limited, allowing the Moon to retain more volatiles and reconciling the giant impact hypothesis with a water-rich Moon.

## Key findings

- Hydrogen escape was diffusion-limited, reducing volatile loss.
- The upper disk was dominated by heavy species, limiting hydrogen diffusion.
- The Moon could have retained significant water, aligning with recent measurements.

## Abstract

The Earth's Moon is thought to have formed from a circumterrestrial disk generated by a giant impact between the proto-Earth and an impactor approximately 4.5 billion years ago. Since the impact was energetic, the disk would have been hot and partially vaporized. This formation process is thought to be responsible for the geochemical observation that the Moon is depleted in volatiles. This model predicts that the Moon should be significantly depleted in water as well, but this appears to contradict some of the recently measured lunar water abundances and D/H ratios that suggest that the Moon is more water-rich than previously thought. Alternatively, the Moon could have retained its water if the upper of the disk were dominated by heavier species because hydrogen would have had to diffuse out from the heavy-element rich disk, and therefore the escape rate would have been limited by this slow diffusion process (diffusion-limited escape). To identify which escape the disk would have experienced and to quantify volatiles loss from the disk, we compute the thermal structure of the Moon-forming disk considering various bulk water abundances and mid-plane disk temperatures. Our calculations show that the upper parts of the Moon-forming disk are dominated by heavy atoms or molecules and hydrogen is a minor species. This indicates that hydrogen escape would have been diffusion-limited, and therefore the amount of lost water and hydrogen would have been small compared to the initial abundance assumed. This result indicates that the giant impact hypothesis can be consistent with the water-rich Moon. Furthermore, since the hydrogen wind would have been weak, the other volatiles would not have escaped either. Thus, the observed volatile depletion of the Moon requires another mechanism.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1812.10502/full.md

## References

73 references — full list in the complete paper: https://tomesphere.com/paper/1812.10502/full.md

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Source: https://tomesphere.com/paper/1812.10502