Self-diffusion in a triple-defect A-B binary system: Monte Carlo simulation

Betlej, J.; Sowa, P.; Kozubski, R.; Murch, G. E.; Belova, I. V.

Title: Self-diffusion in a triple-defect A-B binary system: Monte Carlo simulation
Creator: Betlej, J.; Sowa, P.; Kozubski, R.; Murch, G. E.; Belova, I. V.
Relation: Computational Materials Science Vol. 172, no. 109316
Publisher Link: http://dx.doi.org/10.1016/j.commatsci.2019.109316
Publisher: Elsevier
Resource Type: journal article
Date: 2020
Description: In this comprehensive and detailed study, vacancy-mediated self-diffusion of A- and B-elements in triple-defect B2-ordered ASB1-S binaries is simulated by means of a kinetic Monte Carlo (KMC) algorithm involving atomic jumps to nearest-neighbour (nn) and next-nearest-neighbour (nnn) vacancies. The systems are modelled with an Ising-type Hamiltonian with nn and nnn pair interactions completed with migration barriers dependent on local configurations. Self-diffusion is simulated at equilibrium and temperature-dependent vacancy concentrations are generated by means of a Semi Grand Canonical MC (SGCMC) code. The KMC simulations reproduced the phenomena observed experimentally in Ni-Al intermetallics being typical representatives of the 'triple-defect' binaries. In particular, they yielded the characteristic 'V'-shapes of the isothermal concentration dependencies of A- and B-atom diffusivities, as well as the strong enhancement of the B-atom diffusivity in B-rich systems. The atomistic origins of the phenomenon, as well as other features of the simulated self-diffusion such as temperature and composition dependences of tracer correlation factors and activation energies are analyzed in depth in terms of a number of nanoscopic parameters that are able to be tuned and monitored exclusively with atomistic simulations. The roles of equilibrium and kinetic factors in the generation of the observed features are clearly distinguished and elucidated.
Subject: intermetallics; diffusion; thermodynamic properties; point defects; Monte Carlo simulation; defects: theory
Identifier: http://hdl.handle.net/1959.13/1437973
Identifier: uon:40522
Identifier: ISSN:0927-0256
Language: eng
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