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A systematic survey of Moon-forming giant impacts: Non-rotating bodies

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arxiv 2307.06078 v1 pith:YOIOFED2 submitted 2023-07-12 astro-ph.EP

A systematic survey of Moon-forming giant impacts: Non-rotating bodies

classification astro-ph.EP
keywords impactsmoon-formingbodiesgiantimpactknownbeenconstraints
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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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 controversial post-impact processes. In order to bridge the gap between previous studies and provide a consistent survey of the Moon-forming impact parameter space, we present a systematic study of simulations of potential Moon-forming impacts. In the first paper of this series, we focus on pairwise impacts between non-rotating bodies. Notably, we show that such collisions require a minimum initial angular momentum budget of approximately $2~J_{EM}$ in order to generate a sufficiently massive protolunar disk. We also show that low-velocity impacts ($v_{\infty} \lesssim 0.5~v_{esc}$) with high impactor-to-target mass ratios ($\gamma \to 1$) are preferred to explain the Earth-Moon isotopic similarities. In a follow-up paper, we consider impacts between rotating bodies at various mutual orientations.

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  1. A scaling relation for core heating by giant impacts and implications for dynamo onset

    astro-ph.EP 2026-04 unverdicted novelty 5.0

    SPH simulations produce a scaling relation showing giant impacts heat the core by ~3000 K on average with strong thermal stratification, allowing the core to reach an adiabatic state 290 Myr later consistent with geod...