从冥王星诞生到今天,通过大气逃逸、光化学破坏和撞击侵蚀造成的氮损失

IF 3.8 Q2 ASTRONOMY & ASTROPHYSICS
Perianne E. Johnson, Leslie A. Young, David Nesvorný, Xi Zhang
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引用次数: 0

摘要

我们估算了冥王星在其生命周期内的氮损失,包括巨行星不稳定期,我们称之为 "狂野岁月"。我们分析了53颗模拟冥王星的轨道迁移,这些冥王星是柯伊伯带天体(KBO),在不稳定时期被捕获与海王星产生3:2的平均运动共振。这种轨道迁移将冥王星从 20 至 30 au 带到了它们现在的轨道,接近 40 au,沿着一条非线性路径,包括半主轴为 10 至 100 au 的轨道。我们模拟了这一迁移所产生的热历史,并估算了不断变化的热环境所导致的挥发损失率。由于早期太阳的紫外线辐射增强,狂野年代的光化学破坏率比现在高出 100 倍,但这只导致全球等效层(GEL)损失了 10 米。增强的杰恩斯逃逸率随时间变化很大,预计净损失的全球等效层(GEL)为 100 厘米。此外,我们模拟了迁移过程中的撞击历史,发现撞击是 N2 的净来源,而不是损失,贡献了 ∼100 厘米的 GEL。这100厘米GEL相当于Sputnik Planitia中N2数量的0.1%。因此我们得出结论,冥王星在狂野岁月期间并没有损失过多的挥发物,其原始挥发物存量可以近似为其现在的存量。然而,在这一小部分N2的总损失中,有相当一部分是在荒年期间发生的,因此用现在的速率进行估算将是低估的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nitrogen Loss from Pluto’s Birth to the Present Day via Atmospheric Escape, Photochemical Destruction, and Impact Erosion
We estimate the loss of nitrogen from Pluto over its lifetime, including the giant planet instability period, which we term the “Wild Years.” We analyze the orbital migration of 53 simulated Plutinos, which are Kuiper Belt Objects (KBOs) captured into 3:2 mean-motion resonance with Neptune during the instability. This orbital migration brought the Plutinos from 20 to 30 au to their present-day orbits near 40 au along a nonlinear path that includes orbits with semimajor axes from 10 to 100 au. We model the thermal history that results from this migration and estimate the volatile loss rates due to the ever-changing thermal environment. Due to the early Sun’s enhanced ultraviolet radiation, the photochemical destruction rate during the Wild Years was a factor of 100 higher than the present-day rate, but this only results in a loss of ∼10 m global equivalent layer (GEL). The enhanced Jeans escape rate varies wildly with time, and a net loss of ∼100 cm GEL is predicted. Additionally, we model the impact history during the migration and find that impacts are a net source, not loss, of N2, contributing ∼100 cm GEL. The 100 cm GEL is 0.1% of the amount of N2 in Sputnik Planitia. We therefore conclude that Pluto did not lose an excessive amount of volatiles during the Wild Years, and its primordial volatile inventory can be approximated as its present-day inventory. However, significant fractions of this small total loss of N2 occurred during the Wild Years, so estimates made using present-day rates will be underestimates.
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来源期刊
The Planetary Science Journal
The Planetary Science Journal Earth and Planetary Sciences-Geophysics
CiteScore
5.20
自引率
0.00%
发文量
249
审稿时长
15 weeks
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