Phase-Field Simulation of the Microstructure Evolution in the Eutectic Alloy NiAl-31Cr-3Mo

Kellner, Michael; Schulz, Christiane; Kauffmann, Alexander; Heilmaier, Martin; Nestler, Britta

doi:10.3390/cryst13071046

Cited by 3 publications

(1 citation statement)

References 62 publications

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“…Recent advancements in refining and optimizing the system's thermodynamic description have created new opportunities to explore novel alloy compositions. [ 24 ] Based on the work of Peng et al and an in‐house developed alloy design tool, a novel eutectic NiAl–(Cr,Mo) composite is calculated and compared to the so‐believed Ni 33 Al 33 Cr 28 Mo 6 eutectic alloy. [ 25,26 ] For both alloys, the theoretical results are validated by differential scanning calorimetry (DSC) measurements.…”

Section: Introductionmentioning

confidence: 99%

Design and Characterization of a Novel NiAl–(Cr,Mo) Eutectic Alloy

Titz,

Vollhüter,

Randelzhofer

et al. 2024

Adv Eng Mater

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To enhance the mechanical properties of NiAl‐(Cr,Mo) in‐situ composites for high‐temperature structural use, achieving a regular eutectic microstructure is crucial. A novel alloy with a composition of has been developed that exhibits a significantly reduced solidification interval compared to well studied alloys such as . This advancement results from using the in‐house developed alloy design tool PyMultOpt and CALPHAD analysis to minimize the solidification interval. The refined alloy demonstrates a theoretical solidification interval of 0 K. These results are verified with differential scanning calorimetry (DSC) measurements at different heating rates for the new alloy and compared with the established alloy . The small solidification interval leads to an uniform eutectic microstructure consisting of a (Cr,Mo)‐phase embedded in the NiAl‐matrix without primary NiAl dendrites present. This indicates that deviating from the stoichiometric NiAl composition results in a significantly lower solidification interval and thus in an actual eutectic composition of the NiAl‐(Cr,Mo) system.This article is protected by copyright. All rights reserved.

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Section: Introductionmentioning

confidence: 99%

Design and Characterization of a Novel NiAl–(Cr,Mo) Eutectic Alloy

Titz,

Vollhüter,

Randelzhofer

et al. 2024

Adv Eng Mater

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Misoriented Lamellar Microstructures in Mo‐Si‐Ti Alloy Due to Asymmetrical Nucleation Distance and Interfacial Energies: A Phase‐Field Analysis

Cai,

Wang,

Nestler

2024

Adv Eng Mater

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The material properties are crucially affected by the microstructure formed during solidification, which is typically divided into three stages: (I) Early stage of nucleation in molecule scale, which is beyond the scope of the mean‐field model; (II) Middle stage of nucleation, where the dispersed nuclei have formed; (III) Late stage of nucleation, where the nuclei contact with each other. In previous studies, the formation of the stable eutectic lamellae is mostly based on the assumption that a stable solid‐solid interface has already been established, corresponding to the stage (III), and the growth stage (II) is often overlooked. In the current work, by varying the nucleation density and distance, we propose an alternative mechanism for the misoriented microstructure formation in Mo‐Si‐Ti alloy that considers nucleation stage (II). Furthermore, the misoriention angle as a function of the nucleation density, distance, and the interfacial energies is quantified by systematic phase‐field simulations. The simulated composition distribution reveals the mechanism for the misorientation of eutectic lamellar pairs, which becomes more pronounced when the solids‐fluid interfacial energies are unequal. We expect that the present work provides a potential perspective for the fundamental understanding of misoriented microstructures in solidification.This article is protected by copyright. All rights reserved.

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GPU parallel computing based on PF-LBM method for simulating dendrites growth under natural convection conditions

Li,

Zhu,

Gao

et al. 2024

AIP Advances

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This study introduces a GPU-based parallel computing approach that combines the phase-field model (PF) and the lattice Boltzmann model (LBM). By establishing a coupled multiphase field model incorporating physical external fields such as flow field, temperature field, and solute field, the research simulates the growth of single grains and multiple grains under the influence of natural convection. The variations in dendritic morphology, flow field, and solute field during dendritic solidification processes are observed. Initially, the study analyzes the morphology of equiaxed dendrites and the growth patterns of primary dendrites arms under natural convection conditions. The evolution of equiaxed dendrites in single grains and multiple grains under various conditions is investigated. Furthermore, the study explores the impact of different anisotropy strengths on the growth of single grains and multiple grains under natural convection. Notably, a distinct “necking” phenomenon is observed when the anisotropy strength of a single grain is 0.05. In the case of multiple grains, where competition between dendrites is present in addition to the influence of natural convection, a pronounced “necking” phenomenon is evident at an anisotropy strength of 0.03. Moreover, OpenCL parallel technology is designed on the GPU platform to accelerate the solution of the model. The parallelization of the phase-field model coupled with the LBM model on the GPU demonstrates a clear advantage. The parallel computation based on GPU not only exhibits absolute superiority but also shows more significant acceleration effects as the computational domain increases.

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Phase-Field Simulation of the Microstructure Evolution in the Eutectic Alloy NiAl-31Cr-3Mo

Cited by 3 publications

References 62 publications

Design and Characterization of a Novel NiAl–(Cr,Mo) Eutectic Alloy

Design and Characterization of a Novel NiAl–(Cr,Mo) Eutectic Alloy

Misoriented Lamellar Microstructures in Mo‐Si‐Ti Alloy Due to Asymmetrical Nucleation Distance and Interfacial Energies: A Phase‐Field Analysis

GPU parallel computing based on PF-LBM method for simulating dendrites growth under natural convection conditions

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