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Stimuli‐Triggered Multishape, Multimode, and Multistep Deformations Designed by Microfluidic 3D Droplet Printing

Chenjing Yang, Yao Xiao, Lingjie Hu, Jingyi Chen, Chun‐Xia Zhao, Peng Zhao, Jian Ruan, Zi Liang Wu, Haifeng Yu, David A. Weitz, Dong Chen

2023Small20 citationsDOI

Abstract

Elastomers generally possess low Young's modulus and high failure strain, which are widely used in soft robots and intelligent actuators. However, elastomers generally lack diverse functionalities, such as stimulated shape morphing, and a general strategy to implement these functionalities into elastomers is still challenging. Here, a microfluidic 3D droplet printing platform is developed to design composite elastomers architected with arrays of functional droplets. Functional droplets with controlled size, composition, position, and pattern are designed and implemented in the composite elastomers, imparting functional performances to the systems. The composited elastomers are sensitive to stimuli, such as solvent, temperature, and light, and are able to demonstrate multishape (bow- and S-shaped), multimode (gradual and sudden), and multistep (one- and two-step) deformations. Based on the unique properties of droplet-embedded composite elastomers, a variety of stimuli-responsive systems are developed, including designable numbers, biomimetic flowers, and soft robots, and a series of functional performances are achieved, presenting a facile platform to impart diverse functionalities into composite elastomers by microfluidic 3D droplet printing.

Topics & Concepts

ElastomerMorphingMaterials scienceSoft roboticsMicrofluidicsComposite number3D printingNanotechnologyActuatorComputer scienceComposite materialArtificial intelligenceAdvanced Sensor and Energy Harvesting MaterialsAdvanced Materials and MechanicsModular Robots and Swarm Intelligence
Stimuli‐Triggered Multishape, Multimode, and Multistep Deformations Designed by Microfluidic 3D Droplet Printing | Litcius