轨道共振的新结果

R. Malhotra
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摘要

行星共振的微扰分析通常预测非常低和非常高偏心的共振宽度的奇点和/或发散。我们最近使用非微扰数值分析重新检查了这些分歧的性质,利用庞加莱剖面,但从不同的角度相对于该方法的先前实现。这一视角揭示了共振的精细结构,而传统的方法,包括基于临界共振角的解析、半解析和数值平均方法,仍然隐藏着这些结构。在低偏心率下,一阶共振没有发散宽度,但有两个不对称分支从名义共振位置引出。揭示了连接相邻共振的一系列称为“低偏心谐振桥”的结构。在掠星偏心率处,真正的共振宽度是非发散的。在更高的偏心率下,新的结果揭示了迄今为止未知的共振结构,并表明这些参数区域有一些-尽管不一定是整个-共振振动区域的混乱。高偏心率处的混沌以前被归因于相邻共振的重叠。新的结果揭示了在高偏心率处分岔和相移共振区共存的附加作用。从几何角度出发,将高偏心率相空间结构及其跃迁与旋转框架中共振轨道的形状联系起来。我们概述了未来研究的一些方向,以促进对平均运动共振动力学的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New results on orbital resonances
Abstract Perturbative analyses of planetary resonances commonly predict singularities and/or divergences of resonance widths at very low and very high eccentricities. We have recently re-examined the nature of these divergences using non-perturbative numerical analyses, making use of Poincaré sections but from a different perspective relative to previous implementations of this method. This perspective reveals fine structure of resonances which otherwise remains hidden in conventional approaches, including analytical, semi-analytical and numerical-averaging approaches based on the critical resonant angle. At low eccentricity, first order resonances do not have diverging widths but have two asymmetric branches leading away from the nominal resonance location. A sequence of structures called “low-eccentricity resonant bridges” connecting neighboring resonances is revealed. At planet-grazing eccentricity, the true resonance width is non-divergent. At higher eccentricities, the new results reveal hitherto unknown resonant structures and show that these parameter regions have a loss of some – though not necessarily entire – resonance libration zones to chaos. The chaos at high eccentricities was previously attributed to the overlap of neighboring resonances. The new results reveal the additional role of bifurcations and co-existence of phase-shifted resonance zones at higher eccentricities. By employing a geometric point of view, we relate the high eccentricity phase space structures and their transitions to the shapes of resonant orbits in the rotating frame. We outline some directions for future research to advance understanding of the dynamics of mean motion resonances.
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