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Superior fracture resistance and topology-induced intrinsic toughening mechanism in 3D shell-based lattice metamaterials

Yujia Wang, Yujia Wang, Kunlin Wu, Xuan Zhang, Xiaoyan Li, Yifan Wang, Yifan Wang, Huajian Gao

2024Science Advances50 citationsDOIOpen Access PDF

Abstract

Lattice metamaterials have demonstrated remarkable mechanical properties at low densities. As these architected materials advance toward real-world applications, their tolerance for damage and defects becomes a limiting factor. However, a thorough understanding of the fracture resistance and fracture mechanisms in lattice metamaterials, particularly for the emerging shell-based lattices, has remained elusive. Here, using a combination of in situ fracture experiments and finite element simulations, we show that shell-based lattice metamaterials with Schwarz P minimal surface topology exhibit superior fracture resistance compared to conventional octet truss lattices, with average improvements in initiation toughness up to 150%. This superiority is attributed to the unique shell-based architecture that enables more efficient load transfer and higher energy dissipation through material damage, structural plasticity, and material plasticity. Our study reveals a topology-induced intrinsic toughening mechanism in shell-based lattices and highlights these architectures as a superior design route for creating lightweight and high-performance mechanical metamaterials.

Topics & Concepts

MetamaterialMaterials scienceLattice (music)PlasticityTopology (electrical circuits)ToughnessFracture toughnessTrussDissipationTougheningComposite materialStructural engineeringCondensed matter physicsOptoelectronicsPhysicsAcousticsMathematicsThermodynamicsEngineeringCombinatoricsCellular and Composite StructuresPolymer composites and self-healingAdvanced Materials and Mechanics
Superior fracture resistance and topology-induced intrinsic toughening mechanism in 3D shell-based lattice metamaterials | Litcius