A Systematic Survey of Moon-Forming Giant Impacts. II. Rotating bodies

Thomas Meier, Christian Reinhardt, Miles Timpe, Joachim Stadel, Ben Moore
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Abstract

In the leading theory of lunar formation, known as the giant impact hypothesis, a collision between two planet-size objects resulted in a young Earth surrounded by a circumplanetary debris disk from which the Moon later accreted. The range of giant impacts that could conceivably explain the Earth-Moon system is limited by the set of known physical and geochemical constraints. However, while several distinct Moon-forming impact scenarios have been proposed -- from small, high-velocity impactors to low-velocity mergers between equal-mass objects -- none of these scenarios have been successful at explaining the full set of known constraints, especially without invoking one or more controversial post-impact processes. Allowing for pre-impact rotation of the colliding bodies has been suggested as an avenue which may produce more promising collision outcomes. However, to date, only limited studies of pre-impact rotation have been conducted. Therefore, in the second paper of this series, we focus on pairwise impacts between rotating bodies. Using non-rotating collisions as a baseline, we systematically study the effects of rotation on collision outcomes. We consider nine distinct rotation configurations and a range of rotation rates up to the rotational stability limit. Notably, we identify a population of collisions that can produce low post-impact angular momentum budgets and massive, iron-poor protolunar disks.
月球形成巨型撞击的系统调查。II.旋转体
在关于月球形成的主要理论(即巨型撞击假说)中,两个行星大小的天体之间的碰撞产生了一个年轻的地球,地球周围环绕着一个环行碎屑盘,月球就是后来从这个碎屑盘中产生的。已知的物理和地球化学约束条件限制了可以解释地月系统的巨型撞击的范围。然而,尽管已经提出了几种不同的月球形成撞击方案--从小型高速撞击器到等质量天体之间的低速合并--但这些方案都没有成功地解释全部已知约束条件,尤其是在没有援引一个或多个有争议的撞击后过程的情况下。有人认为,允许碰撞体在碰撞前旋转是一种可能产生更有希望的碰撞结果的途径。然而,迄今为止,关于碰撞前旋转的研究还很有限。因此,在本系列的第二篇论文中,我们将重点关注旋转体之间的成对碰撞。以非旋转碰撞为基线,我们系统地研究了旋转对碰撞结果的影响。我们考虑了九种不同的旋转配置和一系列旋转速率,直至旋转稳定性极限。值得注意的是,我们发现了一个碰撞群体,它可以产生低碰撞后角动量预算和大质量、贫铁的原月盘。
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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