Uncertainties in the Inference of Internal Structure: The Case of TRAPPIST-1 f

The Astrophysical Journal Pub Date : 2025-06-01 DOI:10.3847/1538-4357/add34b

David R. Rice, Chenliang Huang, Jason H. Steffen and Allona Vazan

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Abstract

We use the TRAPPIST-1 system as a model observation of Earth-like planets. The densities of these planets being 1%–10% less than the Earth suggest that the outer planets may host significant hydrospheres. We explore the uncertainty in water mass fraction (wmf) from observed mass and radius. We investigate the interior structure of TRAPPIST-1 f (T1-f) using the open-source solver MAGRATHEA and varying assumptions in the interior model. We find that T1-f likely has a wmf of 16.2% ± 9.9% when considering all possible core mass fractions, and requires 6.9% ± 2.0% water at an Earth-like mantle-to-core ratio. We quantify uncertainties from observational precision, model assumptions, and experimental and theoretical data on the bulk modulus of planet-building materials. We show that observational uncertainties are smaller than model assumptions of mantle mineralogy and core composition but larger than hydrosphere, temperature, and equation-of-state assumptions/uncertainties. Our findings show that while precise mass and radius measurements are crucial, uncertainties in planetary models can often outweigh those from observations, emphasizing the importance of refining both theoretical models and experimental data to better understand exoplanet interiors.

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内部结构推断中的不确定性：以TRAPPIST-1为例

我们使用TRAPPIST-1系统作为类地行星的模型观测。这些行星的密度比地球低1%-10%，这表明外行星可能拥有重要的水圈。我们从观测到的质量和半径来探讨水质量分数（wmf）的不确定性。我们使用开源求解器MAGRATHEA和内部模型中的不同假设来研究TRAPPIST-1 f （T1-f）的内部结构。考虑到所有可能的地核质量分数，我们发现T1-f的wmf可能为16.2%±9.9%，并且在类似地球的地核比下需要6.9%±2.0%的水。我们量化了来自观测精度、模型假设以及关于造行星材料体积模量的实验和理论数据的不确定性。我们发现观测的不确定性小于地幔矿物学和地核组成的模型假设，但大于水圈、温度和状态方程的假设/不确定性。我们的研究结果表明，虽然精确的质量和半径测量是至关重要的，但行星模型的不确定性往往超过观测结果的不确定性，这强调了完善理论模型和实验数据以更好地了解系外行星内部的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Astrophysical Journal

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