Calculation update! New properties have been added to the website for dislocation monopole core structures, dynamic relaxes of both crystal and liquid phases, and melting temperatures! Currently, the results for these properties predominately focus on EAM-style potentials, but the results will be updated for other potentials as the associated calculations finish. Feel free to give us feedback on the new properties so we can improve their representations as needed.
×Warning! Note that elemental potentials taken from alloy descriptions may not work well for the pure species. This is particularly true if the elements were fit for compounds instead of being optimized separately. As with all interatomic potentials, please check to make sure that the performance is adequate for your problem.
×Updated! Potentials that share interactions are now listed as related models.
1990--Ackland-G-J-Vitek-V--Cu
Citation: G.J. Ackland, and V. Vitek (1990), "Many-body potentials and atomic-scale relaxations in noble-metal alloys", Physical Review B, 41(15), 10324-10333. DOI: 10.1103/physrevb.41.10324.
Abstract: We derive empirical many-body potentials for noble-metal alloy systems in the framework of the Finnis-Sinclair model [Philos. Mag. A 50, 45 (1984)] which is based on a second-moment approximation to the tight-binding density of states for transition metals [F. Cyrot, J. Phys. Chem. Solids 29, 1235 (1968)]. The most important extension of the model is a simple incorporation of interspecies interactions which involves fitting the alloying energies. The importance of properly accounting for the local atomic relaxations when constructing the potentials is emphasized. The observed principal features of the phase diagrams of the alloys are all well reproduced by this scheme. Furthermore, reasonable concentration dependences of the alloy lattice parameter and elastic constants are obtained. This leads us to suggest that fine details of the electronic structure may be less important in determining atomic structures than are more global parameters such as atomic sizes and binding energies.
See Computed Properties Notes: A conversion to LAMMPS from MOLDY was performed by G.J. Ackland and submitted on 10 Oct. 2017. This implementation includes the short-range repulsion for radiation studies. Update March 15, 2020: This version was identified to not be compatible with LAMMPS. File(s): retracted
This page displays computed properties for the 1990--Ackland-G-J--Cu--LAMMPS--ipr1 implementation of the 1990--Ackland-G-J-Vitek-V--Cu potential. Computed values for other implementations can be seen by clicking on the links below: