Porous mechanical metamaterials as interacting elastic charges

TL;DR

This paper introduces an analytical geometric framework using elastic charges to accurately model the nonlinear deformation behaviors of 2D porous mechanical metamaterials, aligning well with experimental observations.

Contribution

It presents a novel elastic charge-based approach to describe complex nonlinear responses in porous mechanical metamaterials, enabling better design and understanding.

Findings

Quadrupoles and hexadecapoles effectively match experimental deformation patterns.

The framework accurately predicts shape and orientation changes of pores.

Elastic charges capture the physics of highly deformable porous solids.

Abstract

We present an analytical framework to describe the complex nonlinear response of two-dimensional porous mechanical metamaterials. We adopt a geometric approach to elasticity in which pores are represented by elastic charges, and show that this method captures with high level of accuracy both the shape deformation of individual pores as well as collective deformation patterns resulting from interactions between neighboring pores. Specifically, we show that quadrupoles and hexadecapoles - the two lowest order multipoles available in elasticity - are capable of matching the experimentally observed evolution in shape and relative orientation of the holes in a variety of periodic porous mechanical metamaterials. Our work demonstrates the ability of elastic charges to capture the physics of highly deformable porous solids and paves the way to the development of new theoretical frameworks for the description and rational design of porous mechanical metamaterials.