Orbits of charged particles with an azimuthal initial velocity in a dipole magnetic field

TL;DR

This study systematically analyzes the complex orbital dynamics of charged particles in a dipole magnetic field, revealing classifications of periodic orbits, stability regions, and self-similar structures across energy levels.

Contribution

It provides a detailed classification and analysis of charged particle orbits in a dipole field, including stable and asymmetric periodic orbits, using Lyapunov exponents and escape times.

Findings

Classification of symmetric periodic orbits based on crossing points

Stable quasi-periodic regions linked to asymmetric stable orbits

Self-similar structures in orbit features at different energies

Abstract

Nonintegrable dynamical systems have complex structures in their phase space. Motion of a test charged particle in a dipole magnetic field can be reduced to a 2 degree-of-freedom (2 d.o.f.) nonintegrable Hamiltonian system. We carried out a systematic study of orbits of charged particles with an azimuthal initial velocity in a dipole field via calculation of their Lyapunov characteristic exponents (LCEs) and escape times for a dimensionless energy less and greater than 1/32, respectively. Meridian plane periodic orbits symmetric with respect to the equatorial plane are then identified. We found that 1) symmetric periodic orbits can be classified into several classes based on their number of crossing points on the equatorial plane; 2) the initial conditions of these classes locate on closed loops or closed curves going through the origin; 3) most isolated regions of stable quasi-periodic orbits are associated asymmetric stable periodic orbits; 4) classes of asymmetric periodic orbits either go through the origin or terminate at flat equatorial plane orbits with the other end approaching centers of spiral structures; 5) there are apparent self-similarities in the above features with the decrease of energy.