Bifurcation from periodic solutions of central force problems in the three-dimensional space

Abstract

The paper deals with electromagnetic perturbations of a central force problem of the form equation* ddt ( (x) ) = V'(|x|) x|x| + E(t,x)+x B(t,x), x ∈ R3 \0\, equation* where V (0,+∞) R is a smooth function, E and B are respectively the electric field and the magnetic field, smooth and periodic in time, ∈R is a small parameter. The considered differential operator includes, as special cases, the classical one, (v)=mv, as well as that of special relativity, (v) = mv/1- v 2/c2. We investigate whether non-circular periodic solutions of the unperturbed problem (i.e., with =0) can be continued into periodic solutions for ≠0 small, both for the fixed-period problem and, if the perturbation is time-independent, for the fixed-energy problem. The proof is based on an abstract bifurcation theorem of variational nature, which is applied to suitable Hamiltonian action functionals. In checking the required non-degeneracy conditions we take advantage of the existence of partial action-angle coordinates as provided by the Mishchenko--Fomenko theorem for superintegrable systems. Physically relevant problems to which our results can be applied are homogeneous central force problems in classical mechanics and the Kepler problem in special relativity.