English

The N-Body Problem on Coadjoint Orbits

Mathematical Physics 2025-04-03 v1 math.MP

Abstract

We show (Theorem 3) that the symplectic reduction of the spatial nn-body problem at non-zero angular momentum is a singular symplectic space consisting of two symplectic strata, one for spatial motions and the other for planar motions. Each stratum is realized as coadjoint orbit in the dual of the Lie algebra of the linear symplectic group Sp(2n2)Sp(2n-2). The planar stratum arises as the frontier upon taking the closure of the spatial stratum. We reduce by going to center-of-mass coordinates to reduce by translations and boosts and then performing symplectic reduction with respect to the orthogonal group O(3)O(3). The theorem is a special case of a general theorem (Theorem 2) which holds for the nn-body problem in any dimension dd. This theorem follows largely from a ``Poisson reduction'' theorem, Theorem 1. We achieve our reduction theorems by combining the Howe dual pair perspective of reduction espoused by Lerman-Montgomery-Sjamaar with a normal form arising from a symplectic singular value decomposition due to Xu. We begin the paper by showing how Poisson reduction by the Galilean group rewrites Newton's equations for the nn-body problem as a Lax pair. In section 6.4 we show that this Lax pair representation of the nn-body equations is equivalent to the Albouy-Chenciner representation in terms of symmetric matrices.

Keywords

Cite

@article{arxiv.2504.01272,
  title  = {The N-Body Problem on Coadjoint Orbits},
  author = {Holger Dullin and Richard Montgomery},
  journal= {arXiv preprint arXiv:2504.01272},
  year   = {2025}
}

Comments

28 pages, 2 figures

R2 v1 2026-06-28T22:43:11.252Z