Exploring the Catastrophic Regime: Thermodynamics and Disintegration in Head-On Planetary Collisions

IF 4.7 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Monthly Notices of the Royal Astronomical Society Pub Date : 2024-09-14 DOI:10.1093/mnras/stae2134

Jingyao Dou, Philip J Carter, Simon Lock, Zoë M Leinhardt

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引用次数: 0

Abstract

Head-on giant impacts (collisions between planet-size bodies) are frequently used to study the planet formation process as they present an extreme configuration where the two colliding bodies are greatly disturbed. With limited computing resources, focusing on these extreme impacts eases the burden of exploring a large parameter space. Results from head-on impacts are often then extended to study oblique impacts with angle corrections or used as initial conditions for other calculations, for example, the evolution of ejected debris. In this study, we conduct a detailed investigation of the thermodynamic and energy budget evolution of high-energy head-on giant impacts, entering the catastrophic impacts regime, for target masses between 0.001 and 12 M⊕. We demonstrate the complex interplay of gravitational forces, shock dynamics, and thermodynamic processing in head-on impacts at high energy. Our study illustrates that frequent interactions of core material with the liquid side of the vapour curve could have cumulative effects on the post-collision remnants, leading to fragmentary disintegration occurring at lower impact energy. This results in the mass of the largest remnant diverging significantly from previously developed scaling laws. These findings suggest two key considerations: 1) head-on planetary collisions for different target masses do not behave similarly, so caution is needed when applying scaling laws across a broad parameter space; 2) an accurate model of the liquid-vapour phase boundary is essential for modeling giant impacts. Our findings highlight the need for careful consideration of impact configurations in planetary formation studies, as head-on impacts involve a complex interplay between thermodynamic processing, shocks, gravitational forces, and other factors.

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探索灾难期：行星正面碰撞的热力学与解体

正面巨型撞击（行星大小的天体之间的碰撞）经常被用来研究行星的形成过程，因为在这种极端情况下，两个碰撞天体会受到极大的干扰。在计算资源有限的情况下，关注这些极端撞击可以减轻探索庞大参数空间的负担。迎面撞击的结果通常会通过角度修正扩展到斜撞击的研究中，或者用作其他计算的初始条件，例如抛射碎片的演化。在本研究中，我们详细研究了目标质量在 0.001 和 12 M⊕ 之间、进入灾难性撞击机制的高能迎面巨型撞击的热力学和能量预算演化。我们展示了高能迎面撞击中引力、冲击动力学和热力学处理的复杂相互作用。我们的研究表明，核心物质与蒸汽曲线液态一侧的频繁相互作用可能会对碰撞后的残余物产生累积效应，导致在较低的撞击能量下发生碎裂解体。这导致最大残留物的质量与之前制定的缩放定律有很大偏差。这些发现提出了两个关键的考虑因素：1）不同目标质量的迎面行星碰撞的表现并不相似，因此在广泛的参数空间中应用缩放定律时需要谨慎；2）精确的液-气相边界模型对于巨型撞击的建模至关重要。我们的发现凸显了在行星形成研究中仔细考虑撞击构型的必要性，因为正面撞击涉及热力学处理、冲击、引力和其他因素之间复杂的相互作用。

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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来源期刊

Monthly Notices of the Royal Astronomical Society ASTRONOMY & ASTROPHYSICS-

CiteScore

9.10

自引率

37.50%

发文量

3198

审稿时长

3 months

期刊介绍： Monthly Notices of the Royal Astronomical Society is one of the world''s leading primary research journals in astronomy and astrophysics, as well as one of the longest established. It publishes the results of original research in positional and dynamical astronomy, astrophysics, radio astronomy, cosmology, space research and the design of astronomical instruments.