All-phononic Amplification in Coupled Cantilever Arrays based on Gap Soliton Dynamics

TL;DR

This paper introduces a phononic amplification mechanism using nonlinear band-gap transmission in coupled cantilever arrays, demonstrating how small signals can trigger large soliton responses for potential applications in various physical systems.

Contribution

The paper presents a novel phononic amplification method based on gap soliton dynamics in coupled cantilever arrays, expanding the application scope of nonlinear band-gap transmission phenomena.

Findings

Amplification occurs when a small counter phase pulse triggers a large soliton.

The mechanism relies on nonlinear band-gap transmission near the dispersion relation maximum.

Potential applications include optical, magnonic systems, and logical operations.

Abstract

We present a mechanism of amplification of phonons by phonons on the basis of nonlinear band-gap transmission phenomenon. As a concept the idea may be applied to the various number of systems, however we introduce the specific idea of creating amplification scenario in the chain of coupled cantilever arrays. One chain is driven at the constant frequency located in the upper band of the ladder system, thus no wave enters the system. However the frequency is specifically chosen to be very close to the maximum value of frequency corresponding to dispersion relation of the system. Amplification scenario happens when a counter phase pulse of same frequency with a small amplitude is introduced to the second chain. If both signals exceed a threshold amplitude for the band-gap transmission a large amplitude soliton enters the system - therefore we have an amplifier. Although the concept may be applied in a variety of contexts - all optical or all-magnonic systems, we choose the system of coupled cantilever arrays and represent a clear example of the application of presented conceptual idea. Logical operations is the other probable field, where such mechanism could be used, which might significantly broaden the horizon of considered applications of band-gap soliton dynamics.