Mechanistic insight into the ferritization of austenite in Pb via a discontinuous reaction governed by a migrating liquid film

IF 7.4 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Corrosion Science Pub Date : 2025-10-08 DOI:10.1016/j.corsci.2025.113398

Kin Wing Wong, Peter Szakálos, Christopher Petersson, Dmitry Grishchenko, Pavel Kudinov

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Abstract

The dissolution of austenitic steel in liquid lead-based alloys can induce a phase transformation characterized by a sharp dissolution front separating ferrite and austenite grains, a process commonly referred to as ferritization. Although widely reported, the mechanism driving this transformation remains under debate. This study re-examines ferritization as a discontinuous reaction via a migrating liquid film and proposes a thermodynamically consistent model for the initiation and propagation of the dissolution front. The proposed mechanism is supported by experiments at 500–550°C, literature evidence, and diffusion calculations. Under low oxygen conditions, Cr transport through liquid Pb channels is identified as the rate-limiting step, setting the theoretical corrosion rate in stagnant environments. High-speed erosion-corrosion tests show enhanced corrosion rates, driven by erosion-limited channel lengths that locally boost mass transport. In contrast, under moderate oxygen concentrations relevant for lead-cooled fast reactor (LFR) operation, the rate-limiting step shifts to metal transport across a nanometer-scale amorphous oxide layer at the reaction front. Other Ni-containing austenitic steels, including alumina-forming austenitic (AFA) alloys and Ni-based high-entropy alloys (HEAs) can also be susceptible to discontinuous reactions under direct contact with liquid Pb-based alloys, lacking the self-healing oxide protection as observed in alumina-forming ferritic steels. This limitation may present a concern for the long-term use of bare austenitic steel in liquid Pb environments.

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由迁移液膜控制的不连续反应对铅中奥氏体铁素化的机理研究

奥氏体钢在液态铅基合金中的溶解可引起以铁素体和奥氏体晶粒分离的尖锐溶解锋为特征的相变，这一过程通常被称为铁素体化。尽管有广泛报道，但推动这种转变的机制仍存在争议。本研究通过迁移液膜重新考察了铁化作为不连续反应，并提出了溶解锋的起始和扩展的热力学一致模型。所提出的机制得到了500-550°C实验、文献证据和扩散计算的支持。在低氧条件下，Cr通过液态Pb通道传输被确定为限速步骤，设定了停滞环境下的理论腐蚀速率。高速侵蚀-腐蚀试验表明，受侵蚀限制的通道长度驱动，局部促进了质量输运，从而提高了腐蚀速率。相比之下，在与铅冷快堆（LFR）运行相关的中等氧浓度下，反应前沿的限速步骤转变为金属在纳米尺度非晶态氧化层上的输运。其他含镍奥氏体钢，包括铝形成奥氏体（AFA）合金和镍基高熵合金（HEAs），在与液态铅基合金直接接触时也容易发生不连续反应，缺乏在铝形成铁素体钢中观察到的自修复氧化物保护。这一限制可能会给裸奥氏体钢在液态铅环境中的长期使用带来问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Corrosion Science 工程技术-材料科学：综合

CiteScore

13.60

自引率

18.10%

发文量

763

审稿时长

46 days

期刊介绍： Corrosion occurrence and its practical control encompass a vast array of scientific knowledge. Corrosion Science endeavors to serve as the conduit for the exchange of ideas, developments, and research across all facets of this field, encompassing both metallic and non-metallic corrosion. The scope of this international journal is broad and inclusive. Published papers span from highly theoretical inquiries to essentially practical applications, covering diverse areas such as high-temperature oxidation, passivity, anodic oxidation, biochemical corrosion, stress corrosion cracking, and corrosion control mechanisms and methodologies. This journal publishes original papers and critical reviews across the spectrum of pure and applied corrosion, material degradation, and surface science and engineering. It serves as a crucial link connecting metallurgists, materials scientists, and researchers investigating corrosion and degradation phenomena. Join us in advancing knowledge and understanding in the vital field of corrosion science.