通过卵石吸积形成的岩质行星的气体包层和排气大气的演变

Piia Maria TombergUniversity of Copenhagen, Globe Institute, Anders JohansenUniversity of Copenhagen, Globe Institute
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引用次数: 0

摘要

我们在此介绍岩石行星通过鹅卵石吸积形成和早期演化的数值模拟结果,重点是氢包层的寿命和排气大气的成分。我们模拟的行星质量范围从0.1到5个地球质量,轨道在0.7到1.7 AU之间。出气大气的成分是通过与岩浆海洋自氧化地球物理模型相适应的游离氧分压来计算的。XUV辐射驱动的光蒸发被认为是大气逃逸的主要驱动力。我们模拟的行星仍然低于鹅卵石隔离质量,因此只吸积脆弱的包层。对于 XUV 通量的时间演化,我们考虑了慢速、中速或快速的初始恒星旋转。包层的消失是一个关键事件,它使岩浆海洋得以结晶并释放出大量挥发物。我们模拟的大多数行星的大气成分都以 CO$_2$ 为主。我们的行星总共积累了 11.6 个地球海洋的水,其中大部分进入了内核。比地球轻的行星的水球质量是地球现代海洋质量的几倍,而地球质量在 1 到 3.5 之间的行星的水球质量与我们的行星相当。然而,质量为4-5个地球的行星的水球较小,这是因为挥发物被困在它们巨大的外壳中。总之,我们的模拟结果表明,氢包层很容易从岩石行星上消失,而这种包层的消失会引发固体地幔和大气之间最原始的挥发物分配。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evolution of gas envelopes and outgassed atmospheres of rocky planets formed via pebble accretion
We present here results of numerical simulations of the formation and early evolution of rocky planets through pebble accretion, with an with an emphasis on hydrogen envelope longevity and the composition of the outgassed atmosphere. We model planets with a range in mass from 0.1 to 5 Earth masses that orbit between 0.7 and 1.7 AU. The composition of the outgassed atmosphere is calculated with the partial pressure of free oxygen fit to geophysical models of magma ocean self-oxidation. XUV radiation powered photoevaporation is considered as the main driver of atmospheric escape. We model planets that remain below the pebble isolation mass and hence accrete tenuous envelopes only. We consider slow, medium or fast initial stellar rotation for the temporal evolution of the XUV flux. The loss of the envelope is a key event that allows the magma ocean to crystallise and outgas its bulk volatiles. The atmospheric composition of the majority of our simulated planets is dominated by CO$_2$. Our planets accrete a total of 11.6 Earth oceans of water, the majority of which enters the core. The hydrospheres of planets lighter than the Earth reach several times the mass of the Earth's modern oceans, while the hydrospheres of planets ranging from 1 to 3.5 Earth masses are comparable to those of our planet. However, planets of 4-5 Earth masses have smaller hydrospheres due to trapping of volatiles in their massive mantles. Overall, our simulations demonstrate that hydrogen envelopes are easily lost from rocky planets and that this envelope loss triggers the most primordial partitioning of volatiles between the solid mantle and the atmosphere.
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