Litcius/Paper detail

Encoding reprogrammable properties into magneto-mechanical materials via topology optimization

Zhi Zhao, Xiaojia Shelly Zhang

2023npj Computational Materials50 citationsDOIOpen Access PDF

Abstract

Abstract The properties of materials and structures typically remain fixed after being designed and manufactured. There is a growing interest in systems with the capability of altering their behaviors without changing geometries or material constitutions, because such reprogrammable behaviors could unlock multiple functionalities within a single design. We introduce an optimization-driven approach, based on multi-objective magneto-mechanical topology optimization, to design magneto-active metamaterials and structures whose properties can be seamlessly reprogrammed by switching on and off the external stimuli fields. This optimized material system exhibits one response under pure mechanical loading, and switches to a distinct response under joint mechanical and magnetic stimuli. We discover and experimentally demonstrate magneto-mechanical metamaterials and metastructures that realize a wide range of reprogrammable responses, including multi-functional actuation responses, adaptable snap-buckling behaviors, switchable deformation modes, and tunable bistability. The proposed approach paves the way for promising applications such as magnetic actuators, soft robots, and energy harvesters.

Topics & Concepts

MetamaterialBistabilityMagnetoActuatorTopology (electrical circuits)Topology optimizationMaterials scienceCompliant mechanismComputer scienceRealization (probability)MagnetMechanical engineeringEngineeringStructural engineeringOptoelectronicsElectrical engineeringFinite element methodArtificial intelligenceMathematicsStatisticsTopology Optimization in EngineeringStructural Analysis and OptimizationAdvanced Materials and Mechanics