Growth Kinetics of Boronized Layers and the Diffusion Zone in the Iron-Based A286 Superalloy with the Taylor Expansion Model

IF 1.1 4区材料科学 Q3 METALLURGY & METALLURGICAL ENGINEERING

Protection of Metals and Physical Chemistry of Surfaces Pub Date : 2025-03-26 DOI:10.1134/S2070205124702460

Mourad Keddam, Nait Abdellah Zahra, Brahim Boumaali, Peter Jurči

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Abstract

This work addresses the modelling of growth kinetics for FeB, Fe₂B, and the diffusion zone formed after the solid boriding of the iron-based A286 superalloy. A novel kinetic model was developed to analyze the boron diffusion in this multi-layer system, with a non-linear boron distribution in each phase. The boron concentration profile within each phase was expressed as a function expanded in a second-order Taylor series. Subsequently, the proposed model was used to assess the boron diffusion coefficients in the FeB and Fe₂B layers, as well as in the diffusion zone (DZ), using experimental data from the literature. As a result, the boron activation energies in the FeB, Fe₂B, and DZ layers were determined to be 176.69, 201.05, and 207.80 kJ mol^–1, respectively. Additionally, the experimentally measured layer thicknesses were compared with the predicted values, validating the developed model.

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基于Taylor膨胀模型的铁基A286高温合金中硼化层和扩散区的生长动力学

本文研究了铁基A286高温合金中FeB、Fe2B的生长动力学，以及固体渗硼后形成的扩散区。建立了一种新的动力学模型来分析硼在多层体系中的扩散，硼在各相中的分布是非线性的。每个相内的硼浓度分布表示为二阶泰勒级数展开的函数。随后，利用文献中的实验数据，利用所提出的模型评估了硼在FeB和Fe2B层以及扩散区（DZ）中的扩散系数。结果表明，硼在FeB、Fe2B和DZ层中的活化能分别为176.69、201.05和207.80 kJ mol-1。此外，将实验测量的层厚与预测值进行了比较，验证了所建立的模型。

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来源期刊

Protection of Metals and Physical Chemistry of Surfaces 工程技术-冶金工程

CiteScore

1.90

自引率

18.20%

发文量

审稿时长

4-8 weeks

期刊介绍： Protection of Metals and Physical Chemistry of Surfaces is an international peer reviewed journal that publishes articles covering all aspects of the physical chemistry of materials and interfaces in various environments. The journal covers all related problems of modern physical chemistry and materials science, including: physicochemical processes at interfaces; adsorption phenomena; complexing from molecular and supramolecular structures at the interfaces to new substances, materials and coatings; nanoscale and nanostructured materials and coatings, composed and dispersed materials; physicochemical problems of corrosion, degradation and protection; investigation methods for surface and interface systems, processes, structures, materials and coatings. No principe restrictions exist related systems, types of processes, methods of control and study. The journal welcomes conceptual, theoretical, experimental, methodological, instrumental, environmental, and all other possible studies.