The Influence of Interior Structure and Thermal State on Impact Melt Generation Upon Large Impacts Onto Terrestrial Planets

IF 3.9 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Journal of Geophysical Research: Planets Pub Date : 2025-06-26 DOI:10.1029/2024JE008481

Lukas Manske, Thomas Ruedas, Ana-Catalina Plesa, Philipp Baumeister, Nicola Tosi, Natalia Artemieva, Kai Wünnemann

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Abstract

We investigate the melt production of planetary impacts as a function of planet size ( $R / R_{Earth}$ = 0.1–1.5), impactor size ( $L$ = 1–1,000 km), and core size ratio ( $R_{core} / R$ = 0.2–0.8) using a combination of parameterized convection models and fully dynamical 2D impact simulations. To this end, we introduce a new method to determine impact-induced melt volumes which we normalize by the impactor volume for better comparability. We find that this normalized melt production, or melting efficiency, is enhanced for large planets when struck by smaller impactors, while for small planets, melting efficiency is elevated when impacted by larger impactors. This diverging behavior can be explained by the thickness of the planets' thermal boundary layer and the shapes of their thermal and lithostatic pressure profiles. We also find that melting efficiency maxima are usually highest on Earth-size planets. We show that the melting efficiency is only affected by core size ratio for large cores and older planets, where melt production is decreased significantly compared to smaller core size ratios. Projecting the lunar impactor flux on the generic planets, we find that Moon-sized planets produce the most melt throughout their evolution, relative to planet volume. Contrary to previous scaling laws, our method accounts for melt production by decompression or plastic work in addition to shock melting. We find that traditional scaling laws underestimate melt production on length scales where variations in the target planets' lithology, temperature, and lithostatic pressure become significant. We propose empirical formulas to predict melt generation as a function of radial structure and thermal age.

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大型撞击类地行星时，内部结构和热状态对撞击熔体产生的影响

我们研究了行星撞击产生的熔体作为行星大小的函数（R/ R Earth $R/{R}_{\text{Earth}}$ = 0.1-1.5）。撞击器尺寸（L$ L$ = 1-1,000 km）；和岩心尺寸比（R core /R$ {R}_{\text{core}}/R$ = 0.2 ~ 0.8），采用参数化对流模型和全动态二维撞击模拟相结合的方法。为此，我们引入了一种确定冲击诱发熔体体积的新方法，该方法通过冲击体体积归一化以获得更好的可比性。我们发现，当大型行星受到较小的撞击物撞击时，这种标准化的熔体产量或熔化效率得到提高，而对于小型行星，当受到较大的撞击物撞击时，熔化效率得到提高。这种发散行为可以用行星热边界层的厚度以及它们的热压力和静岩压力剖面的形状来解释。我们还发现，在地球大小的行星上，熔化效率通常是最高的。我们表明，熔化效率仅受大核心和较老的行星的核心尺寸比的影响，在那里，与较小的核心尺寸比相比，熔体产量显着下降。将月球撞击物通量投射到一般行星上，我们发现，相对于行星体积，月球大小的行星在其演化过程中产生的熔体最多。与以前的标度定律相反，我们的方法除了考虑冲击熔化外，还考虑了减压或塑性工作产生的熔体。我们发现，在目标行星的岩性、温度和静岩压力变化变得显著的情况下，传统标度定律低估了长度尺度上的熔体产量。我们提出了经验公式来预测熔体生成作为径向结构和热年龄的函数。

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来源期刊

Journal of Geophysical Research: Planets Earth and Planetary Sciences-Earth and Planetary Sciences (miscellaneous)

CiteScore

8.00

自引率

27.10%

发文量

254

期刊介绍： The Journal of Geophysical Research Planets is dedicated to the publication of new and original research in the broad field of planetary science. Manuscripts concerning planetary geology, geophysics, geochemistry, atmospheres, and dynamics are appropriate for the journal when they increase knowledge about the processes that affect Solar System objects. Manuscripts concerning other planetary systems, exoplanets or Earth are welcome when presented in a comparative planetology perspective. Studies in the field of astrobiology will be considered when they have immediate consequences for the interpretation of planetary data. JGR: Planets does not publish manuscripts that deal with future missions and instrumentation, nor those that are primarily of an engineering interest. Instrument, calibration or data processing papers may be appropriate for the journal, but only when accompanied by scientific analysis and interpretation that increases understanding of the studied object. A manuscript that describes a new method or technique would be acceptable for JGR: Planets if it contained new and relevant scientific results obtained using the method. Review articles are generally not appropriate for JGR: Planets, but they may be considered if they form an integral part of a special issue.