Nonlinear interaction of head$-$on solitary waves in integrable and nonintegrable systems

TL;DR

This paper compares the nonlinear head-on collision of solitary waves in granular chains and fluids, revealing asymmetries and amplitude effects that inform the design of metamaterials and energy systems.

Contribution

It provides a detailed numerical analysis of solitary wave interactions in nonintegrable and integrable systems, highlighting phase shifts and amplitude effects.

Findings

Nonlinear scattering reduces wave amplitude during collision.

Post-collision phase shifts depend on measurement position, not wave amplitude.

Amplitude influences attachment, detachment, and residence times in both systems.

Abstract

This study numerically investigates the nonlinear interaction of head-on solitary waves in a granular chain (a nonintegrable system) and compares the simulation results with the theoretical results in fluid (an integrable system). Three stages (i.e., pre-in-phase traveling stage, central-collision stage, and post-in-phase traveling stage) are identified to describe the nonlinear interaction processes in the granular chain. The nonlinear scattering effect occurs in the central-collision stage, which decreases the amplitude of incident solitary waves. Compared with the leading-time phase in the incident and separation collision processes, the lagging-time phase in the separation collision process is smaller. This asymmetrical nonlinear collision results in an occurrence of leading phase shifts of time and space in the post-in-phase traveling stage. We next find that solitary wave amplitude does not influence the immediate space-phase shift in the granular chain. The space$-$phase shift of the post-in-phase traveling stage is only determined by measurement position rather than wave amplitude. The results are reversed in the fluid. An increase in solitary wave amplitude leads to decreased attachment, detachment and residence times for granular chain and fluid. For the immediate time-phase shift, leading and lagging phenomena appear in the granular chain and the fluid, respectively. These results offer new knowledge for designing mechanical metamaterials and energy-mitigating systems.