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Unraveling elastochemical effects in microstructural evolution of Al–Cu–Ni system through DFT-informed multi-phase field simulations

Through the multi-phase field method, this research explores microstructure evolution within the Al–Cu–Ni system comprising Al-rich FCC, Al2Cu, and Al3Ni intermetallic compounds (IMCs). Notably, the Al3Ni exhibits substantial growth due to its higher free energy magnitude, while the Al2Cu phase dimi...

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Published in:	International journal of solids and structures 2024-08, Vol.300, p.112894, Article 112894
Main Authors:	Poudel, Sachin, Moelans, Nele, Thapa, Rubi, Timofiejczuk, Anna, Panthi, Dhruba, Kunwar, Anil
Format:	Article
Language:	English
Subjects:	Al-alloys Density functional theory Eigenstrain Elastochemical effects Multi-phase field method Thermal calibration
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container_title	International journal of solids and structures
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creator	Poudel, Sachin Moelans, Nele Thapa, Rubi Timofiejczuk, Anna Panthi, Dhruba Kunwar, Anil
description	Through the multi-phase field method, this research explores microstructure evolution within the Al–Cu–Ni system comprising Al-rich FCC, Al2Cu, and Al3Ni intermetallic compounds (IMCs). Notably, the Al3Ni exhibits substantial growth due to its higher free energy magnitude, while the Al2Cu phase diminishes within the FCC matrix. Additionally, this study investigates the impact of heterogeneous elastic effects on these microstructural changes. Density functional theory calculations were employed to determine temperature-dependent elastic tensor at a simulation temperature of 723 K. Initially both cases, simulations with elastic constants at 0 K and 723 K, start with identical grain areas. But by 21.45 ms, deviations notably intensify to 18.18% for single grains, underlining the importance of temperature-calibrated elastic tensor in the phase evolution driven by elastochemical effects. [Display omitted] •Temperature dependence of elasticity investigated via first principle calculations.•Bridging the scales with DFT-informed phase field model.•Elastochemical effects alter the evolution trajectories of Al2Cu, Al3Ni, and FCC phases.
doi_str_mv	10.1016/j.ijsolstr.2024.112894
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subjects	Al-alloys Density functional theory Eigenstrain Elastochemical effects Multi-phase field method Thermal calibration
title	Unraveling elastochemical effects in microstructural evolution of Al–Cu–Ni system through DFT-informed multi-phase field simulations
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