太阳系迁移指向一个新概念:银河宜居轨道

Junichi Baba, Takuji Tsujimoto and Takayuki R. Saitoh
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摘要

天体物理学证据表明,太阳诞生于距离银河系中心 5 kpc 附近的地方,在银河系条带的冠状半径内,大约 6-7 kpc。由于雅可比能量的限制,这给向外迁移带来了挑战,使恒星无法轻易跨越冠层屏障。在这项研究中,我们利用测试粒子模拟来探索太阳两种可能的迁移途径:一种是 "被困 "的情况,即太阳的轨道受到银河系减速条的影响;另一种是 "未被困 "的情况,即太阳的轨道受到动态旋臂的驱动。我们的研究结果表明,这两种机制都可以解释太阳是如何从其诞生半径(≈5 kpc)迁移到目前轨道半径约8.5-9 kpc的。此外,我们还研究了太阳在这些迁移路径上所经历的环境变化,重点是辐射危害和彗星通量的变化,这些变化可能会影响行星的宜居性。这些发现突出了银河系宜居性的动态性质,强调了恒星在银河系内的迁移路径会极大地影响其周围环境和生命存在的可能性。我们提出了 "银河系宜居轨道 "的新概念,它解释了不断演变的银河系结构及其对恒星和行星系统的影响。这项工作有助于深入理解太阳系的迁移及其对银河系内宜居性的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Solar System Migration Points to a Renewed Concept: Galactic Habitable Orbits
Astrophysical evidence suggests that the Sun was born near 5 kpc from the Galactic center, within the corotation radius of the Galactic bar, around 6–7 kpc. This presents challenges for outward migration due to the Jacobi energy constraint, preventing stars from easily overcoming the corotation barrier. In this study, we use test particle simulations to explore two possible migration pathways for the Sun: a “trapped” scenario, where the Sun's orbit was influenced by a slowing Galactic bar, and an “untrapped” scenario driven by dynamic spiral arms. Our results demonstrate that both mechanisms can explain how the Sun migrated from its birth radius (≈5 kpc) to its current orbital radius around 8.5–9 kpc. Furthermore, we investigate the environmental changes experienced by the Sun along these migration pathways, focusing on variations in radiation hazards and comet fluxes, which may have impacted planetary habitability. These findings highlight the dynamic nature of galactic habitability, emphasizing that the path a star takes within the Milky Way can significantly affect its surrounding environment and the potential for life. We propose a new concept of “Galactic habitable orbits,” which accounts for evolving galactic structures and their effects on stellar and planetary systems. This work contributes to a deeper understanding of the solar system's migration and its implications for habitability within the Milky Way.
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