Local minimality properties of circular motions in $1/r^\alpha$ potentials and of the figure-eight solution of the 3-body problem

TL;DR

This paper investigates the local minimality of circular orbits in $1/r^ ext{alpha}$ potentials and the figure-eight solution in the 3-body problem, revealing conditions under which these solutions are minimizers or saddle points.

Contribution

It provides new insights into the minimality properties of circular orbits and the figure-eight solution, combining theoretical analysis with numerical computations.

Findings

Circular solutions are strong local minimizers for $ extalpha > 1$.

They are saddle points for $ extalpha extin (0,1)$.

The figure-eight solution is a strong local minimizer within symmetric periodic loops.

Abstract

We first take into account variational problems with periodic boundary conditions, and briefly recall some sufficient conditions for a periodic solution of the Euler-Lagrange equation to be either a directional, a weak, or a strong local minimizer. We then apply the theory to circular orbits of the Kepler problem with potentials of type $1/r^\alpha, \, \alpha > 0$. By using numerical computations, we show that circular solutions are strong local minimizers for $\alpha > 1$, while they are saddle points for $\alpha \in (0,1)$. Moreover, we show that for $\alpha \in (1,2)$ the global minimizer of the action over periodic curves with degree $2$ with respect to the origin could be achieved on non-collision and non-circular solutions. After, we take into account the figure-eight solution of the 3-body problem, and we show that it is a strong local minimizer over a particular set of symmetric periodic loops.