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Substantially enhanced plasticity of bulk metallic glasses by densifying local atomic packing

Yuan Wu, Di Cao, Yilin Yao, Guosheng Zhang, Jinyue Wang, Leqing Liu, Fengshou Li, Huiyang Fan, Xiongjun Liu, Hui Wang, Xianzhen Wang, Huihui Zhu, Suihe Jiang, Paraskevas Kontis, Dierk Raabe, Baptiste Gault, Zhaoping Lü

2021Nature Communications120 citationsDOIOpen Access PDF

Abstract

Abstract Introducing regions of looser atomic packing in bulk metallic glasses (BMGs) was reported to facilitate plastic deformation, rendering BMGs more ductile at room temperature. Here, we present a different alloy design approach, namely, doping the nonmetallic elements to form densely packed motifs. The enhanced structural fluctuations in Ti-, Zr- and Cu-based BMG systems leads to improved strength and renders these solutes’ atomic neighborhoods more prone to plastic deformation at an increased critical stress. As a result, we simultaneously increased the compressive plasticity (from ∼8% to unfractured), strength (from ∼1725 to 1925 MPa) and toughness (from 87 ± 10 to 165 ± 15 MPa√m), as exemplarily demonstrated for the Zr 20 Cu 20 Hf 20 Ti 20 Ni 20 BMG. Our study advances the understanding of the atomic-scale origin of structure-property relationships in amorphous solids and provides a new strategy for ductilizing BMG without sacrificing strength.

Topics & Concepts

PlasticityMaterials scienceMetalChemical physicsCondensed matter physicsComposite materialChemistryPhysicsMetallurgyMetallic Glasses and Amorphous AlloysPhase-change materials and chalcogenidesGlass properties and applications
Substantially enhanced plasticity of bulk metallic glasses by densifying local atomic packing | Litcius