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Autores principales: Luo, Haiyang, Dorn, Caroline, Deng, Jie
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2401.16394
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author Luo, Haiyang
Dorn, Caroline
Deng, Jie
author_facet Luo, Haiyang
Dorn, Caroline
Deng, Jie
contents Water is an important component of exoplanets, with its distribution, i.e., whether at the surface or deep inside, fundamentally influencing the planetary properties. The distribution of water in most exoplanets is determined by yet-unknown partitioning coefficients at extreme conditions. Our new first-principles molecular dynamics simulations reveal that water strongly partitions into iron over silicate at high pressures and thus would preferentially stay in a planet's core. Furthermore, we model planet interiors by considering the effect of water on density, melting temperature, and water partitioning. The results shatter the notion of water worlds as imagined before: the majority of the bulk water budget (even more than 95%) can be stored deep within the core and the mantle, and not at the surface. For planets more massive than ~6 Earth's mass and Earth-size planets (of lower mass and small water budgets), the majority of water resides deep in the cores of planets, Whether water is assumed to be at the surface or at depth can affect the radius by up to 25% for a given mass. This has drastic consequences for the inferred water distribution in exoplanets from mass-radius data.
format Preprint
id arxiv_https___arxiv_org_abs_2401_16394
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Majority of water hides deep in the interiors of exoplanets
Luo, Haiyang
Dorn, Caroline
Deng, Jie
Earth and Planetary Astrophysics
Water is an important component of exoplanets, with its distribution, i.e., whether at the surface or deep inside, fundamentally influencing the planetary properties. The distribution of water in most exoplanets is determined by yet-unknown partitioning coefficients at extreme conditions. Our new first-principles molecular dynamics simulations reveal that water strongly partitions into iron over silicate at high pressures and thus would preferentially stay in a planet's core. Furthermore, we model planet interiors by considering the effect of water on density, melting temperature, and water partitioning. The results shatter the notion of water worlds as imagined before: the majority of the bulk water budget (even more than 95%) can be stored deep within the core and the mantle, and not at the surface. For planets more massive than ~6 Earth's mass and Earth-size planets (of lower mass and small water budgets), the majority of water resides deep in the cores of planets, Whether water is assumed to be at the surface or at depth can affect the radius by up to 25% for a given mass. This has drastic consequences for the inferred water distribution in exoplanets from mass-radius data.
title Majority of water hides deep in the interiors of exoplanets
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2401.16394