# Propagation of transition fronts in nonlinear chains with non-degenerate   on-site potentials

**Authors:** I.B.Shiroky, O.V.Gendelman

arXiv: 1705.05555 · 2018-03-14

## TL;DR

This paper investigates the propagation of transition fronts in nonlinear chains with non-degenerate on-site potentials, developing a reduced-order model that accurately predicts front characteristics and accounts for damping effects.

## Contribution

It introduces a simple reduced-order model for transition front propagation in nonlinear chains, capturing key features and effects of damping, with analytical predictions validated by numerical results.

## Key findings

- The model predicts shape, frequency, and amplitude of oscillatory tails.
- Front velocities can be far supersonic and associated with shock wave regimes.
- Moderate damping allows perturbative analysis; high damping leads to linear regime.

## Abstract

We address the problem of a front propagation in chains with a bi-stable nondegenerate on-site potential and a nonlinear gradient coupling. For a generic nonlinear coupling, one encounters a special regime of transitions, characterized by extremely narrow fronts, far supersonic velocities of propagation and long waves in the oscillatory tail. This regime can be qualitatively associated with a shock wave. The front propagation can be described with the help of a simple reduced-order model; the latter delivers a kinetic law, which is almost not sensitive to fine details of the on-site potential. Besides, it is possible to predict all main characteristics of the transition front, including its shape and frequency and amplitude of the oscillatory tail. The numerical results are in a good agreement with the analytical predictions. The suggested approach allows one to consider the effects of an external pre-load and on-site damping. When the damping is moderate, the analysis remains in the frame of the reduced-order model. It is possible to consider the solution for the front propagating in the damped chain as a perturbation of the undamped dynamics. This approach yield reasonable predictions. When the damping is high, the transition front enters a completely different asymptotic regime. The gradient nonlinearity generically turns negligible, and the propagating front converges to the exact solution obtained from a simple linear continuous model.

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Source: https://tomesphere.com/paper/1705.05555