Continuum field theory for the deformations of planar kirigami

TL;DR

This paper develops a continuum field theory for planar kirigami, linking design parameters to macroscale deformations through nonlinear PDEs, and validates the model with experiments showing nonlinear wave responses.

Contribution

It introduces a coarse-graining rule and PDE framework that connect kirigami design to emergent deformation behaviors, advancing theoretical understanding.

Findings

Excellent agreement between simulations and experiments.

Identification of nonlinear wave-type responses.

Deformation behavior determined by Poisson's ratio.

Abstract

Mechanical metamaterials exhibit exotic properties at the system level, that emerge from the interactions of many nearly rigid building blocks. Determining these emergent properties theoretically has remained an open challenge outside of a few select examples. Here, for a large class of periodic and planar kirigami, we provide a coarse-graining rule linking the design of the panels and slits to the kirigami's macroscale deformations. The procedure gives a system of nonlinear partial differential equations (PDE) expressing geometric compatibility of angle functions related to the motion of individual slits. Leveraging known solutions of the PDE, we present excellent agreement between simulations and experiments across kirigami designs. The results reveal a surprising nonlinear wave-type response persisting even at large boundary loads, the existence of which is determined completely by the Poisson's ratio of the unit cell.