A continuum mechanics approach for the deformation of non-Euclidean origami generated by piecewise constant nematic director fields

TL;DR

This paper develops a continuum mechanics framework for non-Euclidean origami created by programmed liquid crystal elastomer sheets, enabling design of compatible patterns with prescribed curvature changes for advanced active metamaterials.

Contribution

It introduces a geometric and mechanical analysis of non-Euclidean origami with programmed director fields, including existence proofs and deformation characterizations.

Findings

Constructed compatible director patterns satisfying metric conditions.

Derived analytical relationships between vertex deformations and director patterns.

Designed large-scale non-Euclidean origami patterns with programmable curvature.

Abstract

We merge classical origami concepts with active actuation by designing origami patterns whose panels undergo prescribed metric changes. These metric changes render the system non-Euclidean, inducing non-zero Gaussian curvature at the vertices after actuation. Such patterns can be realized by programming piecewise constant director fields in liquid crystal elastomer (LCE) sheets. In this work, we address the geometric design of both compatible reference director patterns and their corresponding actuated configurations. On the reference configuration, we systematically construct director patterns that satisfy metric compatibility across interfaces. We prove the existence and uniqueness of compatible director fields at a vertex for the generic case, up to orthogonal duals. The Gaussian curvature of the actuated vertex is computed based on the compatible director fields. On the actuated configuration, we develop a continuum mechanics framework to analyze the kinematics of non-Euclidean origami. In particular, we fully characterize the deformation spaces of three-fold and four-fold vertices and establish analytical relationships between their deformations and the director patterns. Building on these kinematic insights, we propose rational designs of large director patterns: one based on a quadrilateral tiling with alternating positive and negative actuated Gaussian curvature, and the other combining three-fold and four-fold vertices governed by a folding angle theorem. Remarkably, both designs achieve compatibility in both the reference and actuated states. We also propose a design strategy for active metamaterials based on the periodic non-Euclidean origami. The active metamaterials can have two modes of motions by folding or stimulating.