Analyzing the Effects of Fifth and Seventh Order Terms in a Generalized Henon-Heiles Potential

TL;DR

This paper investigates how fifth and seventh order terms in a generalized Hénon-Heiles potential influence the system's chaotic behavior, revealing that higher-order terms can either increase or decrease chaos depending on their order.

Contribution

It introduces a detailed analysis of fifth and seventh order terms in the generalized Hénon-Heiles system, highlighting their contrasting effects on system regularity and chaos.

Findings

Fifth-order terms increase regularity in the system.

Seventh-order terms enhance chaotic behavior.

Particles far from critical energy are less chaotic.

Abstract

In 1962, astronomers Michel H\'enon and Carl Heiles studied orbits of stars around centers of galaxies to determine the third integral of motion in galactic dynamics. In order to do this, they reduced the system down to a 2-dimensional axisymmetric Hamiltonian system. Now this is known as the H\'enon-Heiles (HH) System. Due to its apparent simplicity but extremely complicated dynamical behavior, this system is currently a paradigm in dynamical systems. In this paper, we perform a series expansion up to the seventh order of a potential with axial and reflection symmetries. After some transformations, this turns into the generalized H\'enon-Heiles (GHH) system where we separate the fifth and seventh-order terms. We qualitatively analyze this system for energies near the threshold between bounded and unbounded motion with Poincar\'e sections and quantitatively analyze with Lyapunov Exponents. We find that particles far from the critical energy demonstrate less chaos. Additionally, the fifth-order term creates more regularity while the seventh-order term does the opposite.