Envelope solitons in a piezoelectric metamaterial beam obeying the nonlinear Schrödinger equation

IF 6 2区工程技术 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of The Mechanics and Physics of Solids Pub Date : 2025-07-15 DOI:10.1016/j.jmps.2025.106259

Chongan Wang, Alper Erturk

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引用次数: 0

Abstract

Nonlinear metamaterials exhibit rich dynamics, including amplitude-dependent behavior, scale disparities, and bifurcations. These unique characteristics provide additional tunability for nonlinear responses, inspiring the development of functional metamaterials with capabilities such as energy focusing/redirection, mechanical logic, and non-reciprocal acoustics. Piezoelectric metamaterials consisting of arrays of piezoelectric patches bonded on an elastic substrate are well-known for linear concepts such as tunable bandgaps. While these linear metamaterials enable the manipulation of acoustic waves with electric signals, the exploration on nonlinear piezoelectric metamaterials remains limited. In this work, a nonlinear piezoelectric metamaterial is proposed using Duffing-type shunt circuits. The cubic nonlinear inductance in the shunt circuit can be realized through a synthetic impedance circuit with digital control. Homogenization of the governing equations yields a pair of coupled partial differential equations suitable for perturbation analysis. Subsequent analysis in the weakly nonlinear regime reveals that the evolution of a wave packet in the metamaterial is governed by the Nonlinear Schrödinger Equation (NLSE), which is well-known for supporting envelope solitary waves. In addition, NLSE-based solitons can be achieved with either hardening or softening nonlinear shunt inductance, depending on the frequency and wavenumber of the wave. The single envelope soliton solutions of NLSE predicted analytically are validated through nonlinear finite element simulations. These results pave the way for novel nonlinear piezoelectric metamaterials capable of electrically tunable nonlinear wave propagation, with potential applications such as physical reservoir computing leveraging soliton collisions and wave-based mechanical logic.

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服从非线性Schrödinger方程的压电超材料梁中的包络孤子

非线性超材料表现出丰富的动力学，包括振幅依赖行为、尺度差异和分岔。这些独特的特性为非线性响应提供了额外的可调性，激发了具有能量聚焦/重定向、机械逻辑和非互反声学等功能的功能超材料的发展。由弹性衬底上的压电片阵列组成的压电超材料是众所周知的线性概念，如可调带隙。虽然这些线性超材料能够用电信号操纵声波，但对非线性压电超材料的探索仍然有限。本文利用duffing型并联电路提出了一种非线性压电超材料。并联电路中的三次非线性电感可以通过数字控制的合成阻抗电路来实现。控制方程的均匀化得到一对适合摄动分析的耦合偏微分方程。在弱非线性状态下的后续分析表明，超材料中的波包的演化受非线性Schrödinger方程（NLSE）的控制，该方程以支持包络孤立波而闻名。此外，NLSE孤子可以通过硬化或软化非线性电感来实现，这取决于波的频率和波数。通过非线性有限元仿真验证了单包络孤子解的解析预测。这些结果为新型非线性压电超材料铺平了道路，这些材料具有电可调谐非线性波传播的能力，具有潜在的应用，如利用孤子碰撞和基于波的机械逻辑进行物理储层计算。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of The Mechanics and Physics of Solids 物理-材料科学：综合

CiteScore

9.80

自引率

9.40%

发文量

276

审稿时长

52 days

期刊介绍： The aim of Journal of The Mechanics and Physics of Solids is to publish research of the highest quality and of lasting significance on the mechanics of solids. The scope is broad, from fundamental concepts in mechanics to the analysis of novel phenomena and applications. Solids are interpreted broadly to include both hard and soft materials as well as natural and synthetic structures. The approach can be theoretical, experimental or computational.This research activity sits within engineering science and the allied areas of applied mathematics, materials science, bio-mechanics, applied physics, and geophysics. The Journal was founded in 1952 by Rodney Hill, who was its Editor-in-Chief until 1968. The topics of interest to the Journal evolve with developments in the subject but its basic ethos remains the same: to publish research of the highest quality relating to the mechanics of solids. Thus, emphasis is placed on the development of fundamental concepts of mechanics and novel applications of these concepts based on theoretical, experimental or computational approaches, drawing upon the various branches of engineering science and the allied areas within applied mathematics, materials science, structural engineering, applied physics, and geophysics. The main purpose of the Journal is to foster scientific understanding of the processes of deformation and mechanical failure of all solid materials, both technological and natural, and the connections between these processes and their underlying physical mechanisms. In this sense, the content of the Journal should reflect the current state of the discipline in analysis, experimental observation, and numerical simulation. In the interest of achieving this goal, authors are encouraged to consider the significance of their contributions for the field of mechanics and the implications of their results, in addition to describing the details of their work.