Abstract
In order to approximate Gibbs energy functions, a semi-automated framework is introduced for binary and ternary material systems, using Calphad databases. To generate Gibbs energy formulations by means of second-order polynomials, the framework includes a precise approach. Furthermore, an optional extensional step enables the modeling of systems in which a direct generation leads to the unsatisfactory results in the representation of the thermodynamics. Furthermore, an optional extensional step enables the modeling of systems, in which a direct generation leads to the unsatisfactory results, when representing the thermodynamics. Within this extension, the commonly generated functions are modified to satisfy the equilibrium conditions in the observed material systems, leading to a better correlation with thermodynamic databases. The generated Gibbs energy formulations are verified by recalculating the equilibrium concentrations of the phases and rebuilding the phase diagrams in the considered concentration and temperature ranges, prior to the simulation studies. For all comparisons, a close match is achieved between the results and the Calphad databases. As practical examples of the method, phase-field simulation studies for the directional solidification of the binary Ni–35Mo and the ternary NiAl–10Mo eutectic systems are performed. Good agreements between the simulation results and the reported theoretical and experimental studies from literature are found, which indicates the applicability of the presented approaches.Graphical
Highlights
The phase-field method is widely used to investigate the microstructure evolution during the solidification processes in multicomponent material systems
An efficient and semi-automated framework is presented in this paper, so as to generate Gibbs energy formulations for the application in binary and ternary material systems, which is exploited in the introduced phase-field model of [17, 23]
For the generation of Gibbs energy formulations, which are to be used in grand-potential-based phasefield models, an efficient and semi-automated framework is introduced in this work
Summary
The phase-field method is widely used to investigate the microstructure evolution during the solidification processes in multicomponent material systems. If not all required information is sufficiently precalculated, the data need to be approximated by means of interpolation, which can result in a loss of accuracy Another approach is to directly incorporate the Gibbs energy functions from the CALPHAD databases into the model, without calling external libraries. An efficient and semi-automated framework is presented in this paper, so as to generate Gibbs energy formulations for the application in binary and ternary material systems, which is exploited in the introduced phase-field model of [17, 23] The functions in this framework are derived on the basis of a numerical least squares method, using near-equilibrium concentrations, so as to prevent their validity from being solely confined to the equilibrium conditions. Twodimensional simulation studies are conducted, in order to verify the procedure and the resulting Gibbs energy formulations
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
