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Citation: E. Asadi, M.A. Zaeem, S. Nouranian, and M.I. Baskes (2015), "Two-phase solid-liquid coexistence of Ni, Cu, and Al by molecular dynamics simulations using the modified embedded-atom method", Acta Materialia, 86, 169-181. DOI: 10.1016/j.actamat.2014.12.010.
Abstract: The two-phase solid–liquid coexisting structures of Ni, Cu, and Al are studied by molecular dynamics (MD) simulations using the second nearest-neighbor (2NN) modified-embedded atom method (MEAM) potential. For this purpose, the existing 2NN-MEAM parameters for Ni and Cu were modified to make them suitable for the MD simulations of the problems related to the two-phase solid–liquid coexistence of these elements. Using these potentials, we compare calculated low-temperature properties of Ni, Cu, and Al, such as elastic constants, structural energy differences, vacancy formation energy, stacking fault energies, surface energies, specific heat and thermal expansion coefficient with experimental data. The solid–liquid coexistence approach is utilized to accurately calculate the melting points of Ni, Cu, and Al. The MD calculations of the expansion in melting, latent heat and the liquid structure factor are also compared with experimental data. In addition, the solid–liquid interface free energy and surface anisotropy of the elements are determined from the interface fluctuations, and the predictions are compared to the experimental and computational data in the literature.

Notes: Prof. Mohsen Zaeem said that this potential was designed for accurately representing properties from 0K up to the melting point.

LAMMPS pair_style meam (2015--Asadi-E--Cu--LAMMPS--ipr1)
See Computed Properties
Notes: This file was sent by Prof. Mohsen Zaeem (Missouri S&T) on 12 April 2017 and posted on 5 May 2017.
Date Created: October 5, 2010 | Last updated: April 26, 2019