Abstract

The effect of pressure on the interaction parameters (enthalpy of mixing) of face-centered cubic (FCC) and body-centered cubic (BCC) binary solid solution phases has been investigated using atomistic simulations at 0 K based on semi-empirical interatomic potentials (the second nearest-neighbour modified embedded-atom method: 2NN MEAM). First, it is confirmed that the 2NN MEAM interatomic potentials reproduce the pressure dependence of enthalpy and molar volume of pure elements in excellent agreement with thermodynamic modelling and experimental data. The prediction of pressure dependence is then extended to binary solid solutions. It is shown that the pressure dependence of binary interactions is clearly correlated with the sign of excess volume of corresponding solid solution phases. That is, the enthalpy of mixing shifts toward the positive direction with pressure if the excess volume shows a positive deviation from the linear average of constituent elements, while it shifts toward the negative direction in the opposite case. The results can be interpreted well by the functional form for the pressure dependence of Gibbs free energy of solution phases. An atomistic computational approach to estimate the pressure dependence of the excess volume of solution phases is also proposed.

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