Abstract
So far, many research works have been carried out on the heats of solutions for binary alloy systems, but research studies on ternary heats of solutions are still scarce. The thermodynamic properties of the ternary CuNixM(1−x) system, where M = Rh, Sr, and Ir, were predicted using the concept of the thermodynamic properties of binary systems for the ternary system. The idea of predicting CuNixM(1−x) values was regarded as the calculation of the values of heats of solutions and Gibbs free energy for the ternary alloys. The embedded atom method formalism was used to calculate the parameters for the heats of solutions of binary alloys in reasonable compliance with the available experiment and was extended to the prediction of the thermodynamic properties of ternary alloys. The calculated heats of solutions of the ternary systems Cu–Ni–Rh, Cu–Ni–Sr, and Cu–Ni–Ir are −0.814, 16.840, and −1.504 eV, respectively. It was observed that the heat of solution decreases as the value of x increases with Rh and Sr, while the heat of solution increases as x increases for Ir. The stability order is Cu–Ni–Ir, Cu–Ni–Rh, and Cu–Ni–Sr. The liquidus temperature TL at various values of x = 0.00, 0.25, 0.50, 0.75, and 1.00 for the ternary alloys is presented.
Highlights
The thermodynamic properties of materials have been taking a good stand in studying metallic systems, and knowledge about them is necessary for many metallurgical and diffusion controlled processes
We focus on the thermodynamic properties of binary and ternary alloys of copper and nickel based Rh, Sr, and Ir
This paper presents an embedded atom method (EAM) approach to predicting the thermodynamic properties of ternary CuNixM(1−x) systems on the basis of the thermodynamic properties of binary systems included in the investigated ternary system
Summary
The thermodynamic properties of materials have been taking a good stand in studying metallic systems, and knowledge about them is necessary for many metallurgical and diffusion controlled processes. Doping with the selected metals was examined in order to get stable ternary alloys with very low heats of solutions in comparison to the binary counterpart. In this context, it is useful to estimate the thermodynamic data of ternary systems from the constituent binary systems. It is a combination of experimental observation and theoretical modeling and depends on the quality of available experimental data This approach is based on the modeling of ternary systems starting from pure components followed by more complex ones (binary and ternary).. This paper presents an embedded atom method (EAM) approach to predicting the thermodynamic properties of ternary CuNixM(1−x) systems on the basis of the thermodynamic properties of binary systems included in the investigated ternary system
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