Chaotic Diffusion in a Triaxial Galactic Model: an Example of Global Stable Chaos
Received 30 January 2024; accepted 04 July 2024; published 12 August 2024
Author(s): Cincotta P. M., Giordano C. M.
In this work we focus on the chaotic diffusion in the phase space of a triaxial potential
resembling an elliptical galaxy. The transport process is studied in two different action-like
starting spaces in order to cope with circulating and noncirculating orbits. Estimates of the
diffusion rate obtained by means of the variance approach are discussed in detail and their
limitations are exposed. After revisiting the Shannon-entropy-based method from a conceptual
point of view in the framework of simple arguments taken from the information theory, we apply
it to measure changes in the unperturbed actions or integrals of motion of the system for different
sets of small ensembles of random initial conditions. For such sets of ensembles, estimates of the
Lyapunov times are also provided. The results show that, within the chaotic component of the
phase space, the Lyapunov times are shorter than any physical time scale as the Hubble time,
but the diffusion times are much larger than the latter. Thus, we conclude that stable chaos
dominates the dynamics of realistic galactic models.
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