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High‐Performance Organohydrogel Artificial Muscle with Compartmentalized Anisotropic Actuation Under Microdomain Confinement

Longhao Zhang, Hao Yan, Jiajia Zhou, Ziguang Zhao, Jin Huang, Lie Chen, Yunfei Ru, Mingjie Liu

2022Advanced Materials93 citationsDOI

Abstract

Abstract Current hydrogel actuators mostly suffer from weak actuation strength and low responsive speed owing to their solvent diffusion‐induced volume change mechanism. Here a skeletal muscle‐inspired organohydrogel actuator is reported in which solvents are confined in hydrophobic microdomains. Organohydrogel actuator is driven by compartmentalized directional network deformation instead of volume change, avoiding the limitations that originate from solvent diffusion. Organohydrogel actuator has an actuation frequency of 0.11 Hz, 110 times that of traditional solvent diffusion‐driven hydrogel actuators (<10 −3 Hz), and can lift more than 85 times their own weight. This design achieves the combination of high responsive speed, high actuation strength, and large material size, proposing a strategy to fabricate hydrogel actuators comparable with skeletal muscle performance.

Topics & Concepts

ActuatorArtificial muscleMaterials scienceSolventDiffusionLipid microdomainLift (data mining)AnisotropyNanotechnologyVolume (thermodynamics)Mechanism (biology)Composite materialMembraneComputer scienceChemistryPhysicsOpticsThermodynamicsArtificial intelligenceQuantum mechanicsOrganic chemistryData miningBiochemistryAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting MaterialsHydrogels: synthesis, properties, applications