Morse theory for $S$-balanced configurations in the Newtonian $n$-body problem

TL;DR

This paper extends Morse theory to analyze $S$-balanced configurations in the Newtonian $n$-body problem for dimensions $d \\geq 4$, providing lower bounds on their number and implications for periodic motions.

Contribution

It introduces a Morse-theoretic framework for $S$-balanced configurations in higher dimensions, generalizes known results, and improves bounds on periodic solutions in the 4D case.

Findings

Lower bound on the number of $S$-balanced configurations in $\\mathbb{R}^d$ for $d \\geq 4$

A version of the $45^\\circ$-theorem for balanced configurations

Enhanced lower bounds on periodic and quasi-periodic motions in 4D $n$-body problem

Abstract

For the Newtonian (gravitational) $n$-body problem in the Euclidean $d$-dimensional space, the simplest possible solutions are provided by those rigid motions (homographic solutions) in which each body moves along a Keplerian orbit and the configuration of the $n$-body is a constant up to rotations and scalings named \textit{central configuration}. For $d\leq 3$, the only possible homographic motions are those given by central configurations. For $d \geq 4$ instead, new possibilities arise due to the higher complexity of the orthogonal group $O(d)$, as observed by Albouy and Chenciner. For instance, in $\mathbb R^4$ it is possible to rotate in two mutually orthogonal planes with different angular velocities. This produces a new balance between gravitational forces and centrifugal forces providing new periodic and quasi-periodic motions. So, for $d\geq 4$ there is a wider class of $S$-\textit{balanced configurations} (containing the central ones) providing simple solutions of the $n$-body problem, which can be characterized as well through critical point theory. In this paper, we first provide a lower bound on the number of balanced (non-central) configurations in $\mathbb R^d$, for arbitrary $d\geq 4$, and establish a version of the $45^\circ$-theorem for balanced configurations, thus answering some questions raised by Moeckel. Also, a careful study of the asymptotics of the coefficients of the Poincar\'e polynomial of the collision free configuration sphere will enable us to derive some rather unexpected qualitative consequences on the count of $S$-balanced configurations. In the last part of the paper, we focus on the case $d=4$ and provide a lower bound on the number of periodic and quasi-periodic motions of the gravitational $n$-body problem which improves a previous celebrated result of McCord.