木星和土星之间行星轨道的长期稳定性

IF 1.1 4区 物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS
Rudolf Dvorak, Manfred Cuntz
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引用次数: 0

摘要

我们通过研究木星和土星之间的星域,扩展了之前关于太阳系中存在稳定轨道的两项研究。我们将(1)无质量天体、(2)月球质量天体、(3)火星质量天体、(4)地球质量天体和(5)天王星质量天体置于上述区域。请注意,这些天体在我们的模拟框架中是分开考虑的。我们的目标是探索这些天体的轨道稳定性。我们采用的是列积分法,这种方法既快速又成熟,可以求解 N$$ N$$ 体系的相应微分方程。因此,我们考虑了从木星到海王星的天体,包括上述测试天体,这是我们模型模拟的重点。积分结果表明,在某些模型中,位于木星和土星之间区域的测试天体在该区域停留的时间超过 600 Myr。在 5 到 10 au 之间,平均运动共振(MMRs)作用于测试天体,这与论文 I 和 II 的模拟结果类似。我们的模型表明,尽管五个测试天体的质量相差悬殊,但它们的长期稳定性差异相对较小。一般来说,我们发现在 aini=7.04$$ {a}_{\mathrm{ini}}=7.04 $$ 和 7.13 au 之间,轨道大多在 500 万年之内变得不稳定,而在更远的地方,即直到 aini=7.29$$ {a}_{\mathrm{ini}}=7.29 $$ au,稳定的持续时间延长到数亿年。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Long-term stability of planetary orbits between Jupiter and Saturn

We extend our two previous studies on the existence of stable orbits in the Solar System by examining the domain between Jupiter and Saturn. We place (1) a massless object, (2) a Moon-mass object, (3) a Mars-mass object, (4) an Earth-mass object, and (5) a Uranus-mass object in the said region. Note that these objects are considered separately in the framework of our simulations. Our goal is to explore the orbital stability of those objects. We employ the Lie-integration method, which is fast and well established, allowing us to solve the respective differential equations for the N $$ N $$ -body system. Hence, we consider the celestial bodies spanning from Jupiter to Neptune, including the aforementioned test object, the main focus for our model simulations. The integrations indicate that in some models the test objects placed in the region between Jupiter and Saturn reside in that region for more than 600 Myr. Between 5 and 10 au, mean-motion resonances (MMRs) take place acting upon the test objects akin to simulations of Paper I and II. Our models indicate relatively small differences for the long-term stability of the five test objects notwithstanding their vastly different masses. Generally, it is found that between a ini = 7 . 04 $$ {a}_{\mathrm{ini}}=7.04 $$  and 7.13 au the orbits become unstable mostly within 5 million years and further out, that is, up to a ini = 7 . 29 $$ {a}_{\mathrm{ini}}=7.29 $$  au, the duration of stability lengthens to up to hundreds of millions of years.

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来源期刊
Astronomische Nachrichten
Astronomische Nachrichten 地学天文-天文与天体物理
CiteScore
1.80
自引率
11.10%
发文量
57
审稿时长
4-8 weeks
期刊介绍: Astronomische Nachrichten, founded in 1821 by H. C. Schumacher, is the oldest astronomical journal worldwide still being published. Famous astronomical discoveries and important papers on astronomy and astrophysics published in more than 300 volumes of the journal give an outstanding representation of the progress of astronomical research over the last 180 years. Today, Astronomical Notes/ Astronomische Nachrichten publishes articles in the field of observational and theoretical astrophysics and related topics in solar-system and solar physics. Additional, papers on astronomical instrumentation ground-based and space-based as well as papers about numerical astrophysical techniques and supercomputer modelling are covered. Papers can be completed by short video sequences in the electronic version. Astronomical Notes/ Astronomische Nachrichten also publishes special issues of meeting proceedings.
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