Atomic Modeling and Simulation of AlCoCrCuFeNi Multi-Principal-Element Alloy

Shao Qing Wang

doi:10.4028/www.scientific.net/MSF.749.479

Paper Titles

Size Dependent Mechanical Properties of Graphene Nanoribbons: Molecular Dynamics Simulation
p.456

The Effect of the Size and Electronic Factor on Occupation and Magnetic Property of Co Addition in L10 FePt Alloy
p.461

First-Principles Study on the Thermodynamic Properties of Nb, Cr₂Nb and Nb₅Si₃ Alloys
p.466

Research on the out of Square of H-Beams
p.473

Atomic Modeling and Simulation of AlCoCrCuFeNi Multi-Principal-Element Alloy
p.479

Influence of Deformation and Quenching Temperature on Structures and Properties of High Nitrogen Stainless Bearing Steel
p.484

Precipitate Behavior and Microstructure Evolution of γ’ Phase in Ni-Al Alloys with the Internal Elastic Strain
p.491

Research on Flow Behavior of Advanced High Strength Steel at Elevated Temperature
p.498

Simulation and Technology Optimization for Rolling Web Wave of Large Size H-Beam
p.504

HomeMaterials Science ForumMaterials Science Forum Vol. 749Atomic Modeling and Simulation of AlCoCrCuFeNi...

Atomic Modeling and Simulation of AlCoCrCuFeNi Multi-Principal-Element Alloy

Abstract:

Atomic structure model of bulk AlCoCrCuFeNi multi-principal-element alloy was build by following the principle of maximum entropy. Morse pair-potentials to describe the inter-atomic interaction among neighboring atoms in the alloy were generated directly from first-principles calculations within density-functional theory. Molecular statics simulation was carried out to achieve the optimized atomic configuration of AlCoCrCuFeNi alloy. The results show that the crystallographic behavior in lattice structure observed experimentally is just caused by the average of the disordered atomic position and composition in wide range since there is neither short-range nor long-range order in the local atomic arrangement of this kind of materials.