{"title":"The Integral Manifolds of the 4 Body Problem with Equal Masses: Bifurcations at Relative Equilibria","authors":"Christopher K. McCord","doi":"10.1007/s10884-024-10391-6","DOIUrl":null,"url":null,"abstract":"<p>In the <i>N</i>-body problem, it is classical that there are conserved quantities of center of mass, linear momentum, angular momentum and energy. The level sets <span>\\(\\mathfrak {M}(c,h)\\)</span> of these conserved quantities are parameterized by the angular momentum <i>c</i> and the energy <i>h</i>, and are known as the <i>integral manifolds</i>. A long-standing goal has been to identify the bifurcation values, especially the bifurcation values of energy for fixed non-zero angular momentum, and to describe the integral manifolds at the regular values. Alain Albouy identified two categories of singular values of energy: those corresponding to bifurcations at relative equilibria; and those corresponding to “bifurcations at infinity”, and demonstrated that these are the only possible bifurcation values. This work completes the identification of bifurcations for the four-body problem with equal masses, confirming that, in this setting, Albouy’s necessary conditions for bifurcation are also sufficient conditions: bifurcations of the integral manifolds occur at all of the singular values of energy. A recent study examined the bifurcations at infinity; this work evaluates the four bifurcations at relative equilibria. To establish that the topology of the integral manifolds changes at each of these values, and to describe the manifolds at the regular values of energy, the homology groups of the integral manifolds are computed for the five energy regions on either side of the singular values. The homology group calculations establish that all four energy levels are indeed bifurcation values, and allows some of the global properties of the integral manifolds to be explored.</p>","PeriodicalId":15624,"journal":{"name":"Journal of Dynamics and Differential Equations","volume":"48 1","pages":""},"PeriodicalIF":1.4000,"publicationDate":"2024-09-09","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Dynamics and Differential Equations","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1007/s10884-024-10391-6","RegionNum":4,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS","Score":null,"Total":0}
引用次数: 0
Abstract
In the N-body problem, it is classical that there are conserved quantities of center of mass, linear momentum, angular momentum and energy. The level sets \(\mathfrak {M}(c,h)\) of these conserved quantities are parameterized by the angular momentum c and the energy h, and are known as the integral manifolds. A long-standing goal has been to identify the bifurcation values, especially the bifurcation values of energy for fixed non-zero angular momentum, and to describe the integral manifolds at the regular values. Alain Albouy identified two categories of singular values of energy: those corresponding to bifurcations at relative equilibria; and those corresponding to “bifurcations at infinity”, and demonstrated that these are the only possible bifurcation values. This work completes the identification of bifurcations for the four-body problem with equal masses, confirming that, in this setting, Albouy’s necessary conditions for bifurcation are also sufficient conditions: bifurcations of the integral manifolds occur at all of the singular values of energy. A recent study examined the bifurcations at infinity; this work evaluates the four bifurcations at relative equilibria. To establish that the topology of the integral manifolds changes at each of these values, and to describe the manifolds at the regular values of energy, the homology groups of the integral manifolds are computed for the five energy regions on either side of the singular values. The homology group calculations establish that all four energy levels are indeed bifurcation values, and allows some of the global properties of the integral manifolds to be explored.
在 N 体问题中,经典的守恒量是质心、线动量、角动量和能量。这些守恒量的水平集(\mathfrak {M}(c,h)\) 以角动量 c 和能量 h 为参数,被称为积分流形。长期以来,人们一直致力于确定分叉值,特别是固定非零角动量的能量分叉值,并描述规则值下的积分流形。阿兰-阿尔布伊确定了两类能量奇异值:对应于相对平衡的分岔值;以及对应于 "无穷大分岔 "的分岔值,并证明这些是唯一可能的分岔值。这项工作完成了对质量相等的四体问题分岔的识别,证实了在这种情况下,阿尔布伊的分岔必要条件也是充分条件:积分流形的分岔出现在能量的所有奇异值上。最近的一项研究考察了无穷大处的分岔;本研究评估了相对平衡处的四个分岔。为了确定积分流形的拓扑结构在每个奇异值处都会发生变化,并描述能量规则值处的流形,我们计算了奇异值两侧五个能量区域的积分流形的同调群。同调群计算确定了所有四个能级确实都是分叉值,并允许探索积分流形的一些全局属性。
期刊介绍:
Journal of Dynamics and Differential Equations serves as an international forum for the publication of high-quality, peer-reviewed original papers in the field of mathematics, biology, engineering, physics, and other areas of science. The dynamical issues treated in the journal cover all the classical topics, including attractors, bifurcation theory, connection theory, dichotomies, stability theory and transversality, as well as topics in new and emerging areas of the field.