Newton's cradles in optics: From to N-soliton fission to soliton chains

TL;DR

This paper demonstrates a mechanism for creating a Newton's cradle in nonlinear optical fibers driven by third-order dispersion, revealing complex soliton interactions, fission processes, and potential broadband supercontinuum generation.

Contribution

It introduces a novel optical Newton's cradle mechanism based on third-order dispersion, showing how N-solitons split and interact in fiber optics, extending the concept beyond mechanical systems.

Findings

The NC structure forms during N-soliton fission in fibers.

Tallest soliton escapes after multiple collisions, leaving a bound state.

The regime is robust against perturbations like Raman effects.

Abstract

A mechanism for creating a Newton's cradle (NC) in nonlinear light wavetrains under the action of the third-order dispersion (TOD) is demonstrated. The formation of the NC structure plays an important role in the process of fission of higher-order N-solitons in optical fibers. After the splitting of the initial N--soliton into a nonuniform chain of fundamental quasi-solitons, the tallest one travels along the entire chain, through consecutive collisions with other solitons, and then escapes, while the remaining chain of pulses stays as a bound state, due to the radiation-mediated interaction between them. Increasing the initial soliton's order, $N$, leads to the transmission through, and release of additional solitons with enhanced power, along with the emission of radiation, which may demonstrate a broadband supercontinuum spectrum. The NC dynamical regime remains robust in the presence of extra perturbations, such as the Raman and self-steepening effects, and dispersions terms above the third order. It is demonstrated that essentially the same NC mechanism is induced by the TOD in finite segments of periodic wavetrains (in particular, soliton chains). A strong difference from the mechanical NC is that the TOD-driven pulse passing through the soliton array collects energy and momentum from other solitons. Thus, uniform and non-uniforms arrays of nonlinear wave pulses offer an essential extension of the mechanical NC, in which the quasi-particles, unlike mechanical beads, interact inelastically, exchanging energy and generating radiation. Nevertheless, the characteristic phenomenology of NC chains may be clearly identified in these nonlinear-wave settings too.