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Computing grain boundary diagrams of thermodynamic and mechanical properties

Chongze Hu, Yanwen Li, Zhiyang Yu, Jian Luo

2021npj Computational Materials24 citationsDOIOpen Access PDF

Abstract

Abstract Computing the grain boundary (GB) counterparts to bulk phase diagrams represents an emerging research direction. Using a classical embrittlement model system Ga-doped Al alloy, this study demonstrates the feasibility of computing temperature- and composition-dependent GB diagrams to represent not only equilibrium thermodynamic and structural characters, but also mechanical properties. Specifically, hybrid Monte Carlo and molecular dynamics (MC/MD) simulations are used to obtain the equilibrium GB structure as a function of temperature and composition. Simulated GB structures are validated by aberration-corrected scanning transmission electron microscopy. Subsequently, MD tensile tests are performed on the simulated equilibrium GB structures. GB diagrams are computed for not only GB adsorption and structural disorder, but also interfacial structural and chemical widths, MD ultimate tensile strength, and MD tensile toughness. This study suggests a research direction to investigate GB composition–structure–property relationships via computing GB diagrams of thermodynamic, structural, and mechanical (or potentially other) properties.

Topics & Concepts

Materials scienceMolecular dynamicsUltimate tensile strengthMonte Carlo methodPhase diagramThermodynamicsGrain boundaryEmbrittlementScalingMicrostructurePhase (matter)ChemistryPhysicsComposite materialComputational chemistryGeometryMathematicsStatisticsOrganic chemistryMicrostructure and mechanical propertiesHigh Temperature Alloys and CreepHydrogen embrittlement and corrosion behaviors in metals
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