Phase Space Structure and Transport in a Caldera Potential Energy Surface

TL;DR

This paper analyzes phase space transport in a 2D caldera potential energy surface using nonlinear dynamics, identifying mechanisms governing trajectory entrance, trapping, and exit related to invariant manifolds and saddle points.

Contribution

It categorizes phase space structures into four cases based on energy and stability, and elucidates three mechanisms controlling transport in caldera PES.

Findings

Identified four distinct phase space structures governing transport.

Computed invariant manifolds of periodic orbits in the caldera.

Described three mechanisms controlling entrance, trapping, and exit of trajectories.

Abstract

We study phase space transport in a 2D caldera potential energy surface (PES) using techniques from nonlinear dynamics. The caldera PES is characterized by a flat region or shallow minimum at its center surrounded by potential walls and multiple symmetry related index one saddle points that allow entrance and exit from this intermediate region.We have discovered four qualitatively distinct cases of the structure of the phase space that govern phase space transport. These cases are categorized according to the total energy and the stability of the periodic orbits associated with the family of the central minimum, the bifurcations of the same family, and the energetic accessibility of the index one saddles. In each case we have computed the invariant manifolds of the unstable periodic orbits of the central region of the potential and the invariant manifolds of the unstable periodic orbits of the families of periodic orbits associated with the index one saddles. We have found that there are three distinct mechanisms determined by the invariant manifold structure of the unstable periodic orbits govern the phase space transport. The first mechanism explains the nature of the entrance of the trajectories from the region of the low energy saddles into the caldera and how they may become trapped in the central region of the potential. The second mechanism describes the trapping of the trajectories that begin from the central region of the caldera, their transport to the regions of the saddles, and the nature of their exit from the caldera. The third mechanism describes the phase space geometry responsible for the dynamical matching of trajectories originally proposed by Carpenter and described in Collins et al. (2014) for the two dimensional caldera PES that we consider.