Collective Coordinates Theory for Discrete Soliton Ratchets in the sine-Gordon Model

TL;DR

This paper develops a collective coordinate theory for soliton ratchets in the damped discrete sine-Gordon model driven by biharmonic forces, explaining key phenomena and complex dynamical regimes.

Contribution

It introduces a two-coordinate ansatz and the Generalized Travelling Wave Method to qualitatively explain soliton ratchet mechanisms and phenomena.

Findings

Accounts for non-zero depinning threshold

Explains non-sinusoidal velocity behavior

Describes complex dynamical regimes

Abstract

A collective coordinate theory is develop for soliton ratchets in the damped discrete sine-Gordon model driven by a biharmonic force. An ansatz with two collective coordinates, namely the center and the width of the soliton, is assumed as an approximated solution of the discrete non-linear equation. The evolution of these two collective coordinates, obtained by means of the Generalized Travelling Wave Method, explains the mechanism underlying the soliton ratchet and captures qualitatively all the main features of this phenomenon. The theory accounts for the existence of a non-zero depinning threshold, the non-sinusoidal behaviour of the average velocity as a function of the difference phase between the harmonics of the driver, the non-monotonic dependence of the average velocity on the damping and the existence of non-transporting regimes beyond the depinning threshold. In particular it provides a good description of the intriguing and complex pattern of subspaces corresponding to different dynamical regimes in parameter space.