Machine Learning-Guided Design of Non-Reciprocal and Asymmetric Elastic Chiral Metamaterials

TL;DR

This paper uses machine learning, specifically Bayesian optimization, to design chiral metamaterials with simultaneous high non-reciprocity and elastic asymmetry, revealing mechanisms behind their unique properties.

Contribution

It introduces a machine learning framework for optimizing passive chiral metamaterials to achieve both non-reciprocity and elastic asymmetry, a previously open challenge.

Findings

Chiral metamaterials can exhibit multiple contact states under loading.

ML-based optimization identifies designs with high non-reciprocity and stiffness asymmetry.

Design insights reveal contact state variability as key to properties.

Abstract

There has been significant recent interest in the mechanics community to design structures that can either violate reciprocity, or exhibit elastic asymmetry or odd elasticity. While these properties are highly desirable to enable mechanical metamaterials to exhibit novel wave propagation phenomena, it remains an open question as to how to design passive structures that exhibit both significant non-reciprocity and elastic asymmetry. In this paper, we first define several design spaces for chiral metamaterials leveraging specific design parameters, including the ligament contact angles, the ligament shape, and circle radius. Having defined the design spaces, we then leverage machine learning approaches, and specifically Bayesian optimization, to determine optimally performing designs within each design space satisfying maximal non-reciprocity or stiffness asymmetry. Finally, we perform multi-objective optimization by determining the Pareto optimum and find chiral metamaterials that simultaneously exhibit high non-reciprocity and stiffness asymmetry. Our analysis of the underlying mechanisms reveals that chiral metamaterials that can display multiple different contact states under loading in different directions are able to simultaneously exhibit both high non-reciprocity and stiffness asymmetry. Overall, this work demonstrates the effectiveness of employing ML to bring insights to a novel domain with limited prior information, and more generally will pave the way for metamaterials with unique properties and functionality in directing and guiding mechanical wave energy.