Future trajectories of the Solar System: dynamical simulations of stellar encounters within 100 au

Sean N. Raymond, Nathan A. Kaib, Franck Selsis, Herve Bouy
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Abstract

Given the inexorable increase in the Sun's luminosity, Earth will exit the habitable zone in ~1 Gyr. There is a negligible chance that Earth's orbit will change during that time through internal Solar System dynamics. However, there is a ~1% chance per Gyr that a star will pass within 100 au of the Sun. Here, we use N-body simulations to evaluate the possible evolutionary pathways of the planets under the perturbation from a close stellar passage. We find a ~92% chance that all eight planets will survive on orbits similar to their current ones if a star passes within 100 au of the Sun. Yet a passing star may disrupt the Solar System, by directly perturbing the planets' orbits or by triggering a dynamical instability. Mercury is the most fragile, with a destruction rate (usually via collision with the Sun) higher than that of the four giant planets combined. The most probable destructive pathways for Earth are to undergo a giant impact (with the Moon or Venus) or to collide with the Sun. Each planet may find itself on a very different orbit than its present-day one, in some cases with high eccentricities or inclinations. There is a small chance that Earth could end up on a more distant (colder) orbit, through re-shuffling of the system's orbital architecture, ejection into interstellar space (or into the Oort cloud), or capture by the passing star. We quantify plausible outcomes for the post-flyby Solar System.
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太阳系的未来轨迹:100天文单位内恒星碰撞的动力学模拟
考虑到太阳亮度的不可阻挡的增加,地球将在1gyr内离开宜居带。在此期间,地球轨道通过太阳系内部动力学变化的可能性微乎其微。然而,每一年有1%的机会,一颗恒星会在距离太阳100天文单位的范围内经过。在这里,我们使用n体模拟来评估行星在近距离恒星通道扰动下可能的进化路径。我们发现,如果有一颗恒星在距离太阳100天文单位的范围内经过,那么所有8颗行星都有92%的机会在与当前相似的轨道上存活下来。然而,一颗路过的恒星可能会通过直接扰乱行星的轨道或引发动力不稳定来破坏太阳系。水星是最脆弱的,它的毁灭率(通常通过与太阳的碰撞)比这四颗巨行星的总和还要高。对地球来说,最可能的破坏途径是经历巨大的撞击(与月球或金星)或与太阳相撞。每颗行星可能会发现自己的轨道与现在的轨道非常不同,在某些情况下有很高的离心率或倾斜度。有一个很小的机会,地球可能会在一个更遥远(更冷)的轨道上结束,通过重新洗选系统的轨道结构,弹射到星际空间(或奥尔特云),或被路过的恒星捕获。我们量化了飞掠太阳系后的可能结果。
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