Litcius/Paper detail

Spatiotemporally programmed dielectric liquid crystal elastomer: Electro-reversible 3D morphing via inverse 4D printing

Huiyao Zhao, Zike Chen, Jiahao Li, Yingwu Luo, Zhike Peng, Guoyong Mao, Rui Xiao, Jie Mao

2025Science Advances15 citationsDOIOpen Access PDF

Abstract

Programmable shape-morphing materials offer transformative potential in soft robotics and biomedical engineering, yet achieving reversible and precise control over complex 3D deformations remains a notable challenge due to the difficulty in spatially programming nonlinear mechanics. Here, we introduce a shear-assisted digital light-processing 4D printing strategy for spatiotemporal programming the mechanical anisotropy of dielectric liquid crystal elastomers (DLCEs). The printed DLCE actuators exhibit reversible multidimensional shape morphing (e.g., bending, twisting, and complex curved surfaces) under electric fields, governed by regional stiffness gradients. An inverse design algorithm is also developed to convert target 3D surfaces into executable printing tasks. Submillimeter-scale fidelity in reconstructing complex geometries, such as a panda face, a biomimetic plant and the Yellow River's landform, demonstrates capabilities applicable to soft robotics and adaptive systems.

Topics & Concepts

MorphingSoft roboticsRoboticsComputer scienceActuatorLiquid crystalMaterials scienceArtificial intelligenceNonlinear systemBiomimeticsNanotechnologyInverseRobot3D printingMechanical engineeringCloakRealization (probability)Inverse problemExecutableAnisotropyDielectricConstructiveStiffnessCastingComputer visionElectroactive polymersSmart materialDigital Light ProcessingHigh fidelityTransformative learningElastomerBiological systemAdvanced Materials and MechanicsDielectric materials and actuatorsSoft Robotics and Applications