Open AccessMolecular dynamics simulation of the solidification of AlCoCuFeNi high–entropy alloy nanowire
Author(s) -
O. I. Kushnerov
Publication year - 2019
Publication title -
journal of physics and electronics
Language(s) - English
Resource type - Journals
eISSN - 2664-3626
pISSN - 2616-8685
DOI - 10.15421/331925
Subject(s) - nanowire , molecular dynamics , materials science , radial distribution function , amorphous solid , alloy , crystallization , embedded atom model , lattice (music) , thermodynamics , condensed matter physics , nanotechnology , crystallography , composite material , chemistry , physics , computational chemistry , acoustics
Molecular dynamics simulation of the solidification behavior of AlCoCuFeNi nanowire was carried out basing on the embedded atom potential with different cooling rates (1∙10, 1∙10, and 1∙10 K/s). To simulate an infinite nanowire, a periodical boundary condition along the nanowire axis direction was applied. The crystallization of the nanowire was characterized by studying the temperature dependence of the potential energy. The adaptive common neighbor analysis (CNA) was performed and the radial distribution function (RDF) was calculated to determine the structure and lattice parameters of phases of the AlCoCuFeNi nanowire. It has been shown that the final structure of investigated nanoparticle changes from amorphous to crystalline with decreasing of the rate of cooling.
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