Hydrogen in metallic alloys ─ embrittlement and enhanced plasticity: a review

IF 2.7 4区 材料科学 Q3 ELECTROCHEMISTRY Corrosion Reviews Pub Date : 2024-03-18 DOI:10.1515/corrrev-2022-0060
Valentin G. Gavriljuk, V. Shyvaniuk, S. Teus
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Abstract

The evolution of ideas concerning the nature of hydrogen embrittlement of engineering metallic materials is described based on a number of the proposed hypotheses and corresponding experiments. The main attention is paid to two of them, namely hydrogen-enhanced decohesion (HEDE) and hydrogen-enhanced localized plasticity (HELP). Recent attempts to interconnect the both models as HELP + HEDE and HELP-mediated HEDE ones are also estimated. A conclusion is made that HELP model is preferential for understanding the entire array of experimental data with a caveat that it is necessary to consider the chemical nature of hydrogen atoms and view them not only as point defects. Based on the studies of hydrogen effect on the atomic interactions in iron, nickel, titanium, and its alloys, it is shown that the electron approach to HELP phenomenon adequately describes two competitive features of hydrogen behavior in metals: increased brittleness and enhanced plasticity. Due to the increase in the concentration of free electrons, hydrogen decreases the elasticity moduli, which causes the crystal lattice to soften. For this reason, the formation of hydrogen atmospheres around the dislocations decreases the start stress of dislocation sources, as well as line tension of emitted dislocations, enhancing thereby their mobility, and weakens repulsion between dislocations in their pile-ups. The range of temperatures and strain rates in which hydrogen embrittlement occurs is controlled by the enthalpies of hydrogen atoms’ diffusion and their binding to dislocations. The resulting consequences for mechanical properties depend on the short-range atomic order, SRO, which inherently occurs in the metallic solid solutions and localizes plastic deformation both in the cases of short-range atomic ordering and of short-range atomic decomposition. Hydrogen enhances slip localization because of its different solubility in the submicrovolumes of short-range decomposed solid solutions. If SRO is absent or not remarkably formed, the hydrogen-increased concentration of free electrons results in enhanced plasticity. Available positive hydrogen effects on the plasticity of titanium β-alloys and austenitic steels are presented and interpreted.
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金属合金中的氢 - 脆性和增强塑性:综述
根据提出的一些假设和相应的实验,阐述了有关工程金属材料氢脆性质的观点演变。主要关注的是其中两个模型,即氢增强脱粘 (HEDE) 和氢增强局部塑性 (HELP)。此外,还对最近尝试将这两种模型互联为 HELP + HEDE 和 HELP 介导的 HEDE 模型进行了估算。得出的结论是,HELP 模型更适于理解所有实验数据,但需要注意的是,有必要考虑氢原子的化学性质,而不仅仅将其视为点缺陷。基于氢对铁、镍、钛及其合金中原子相互作用影响的研究表明,HELP 现象的电子方法充分描述了金属中氢行为的两个竞争特征:脆性增加和塑性增强。由于自由电子浓度的增加,氢会降低弹性模量,从而导致晶格软化。因此,在位错周围形成的氢气环境会降低位错源的起始应力以及发射位错的线拉力,从而增强位错的流动性,并减弱位错堆积时位错之间的排斥力。氢脆发生的温度和应变速率范围受氢原子扩散焓和与位错结合焓的控制。由此对机械性能产生的影响取决于金属固溶体中固有的短程原子有序(SRO),在短程原子有序和短程原子分解的情况下,都会使塑性变形局部化。由于氢在短程分解固溶体亚微观体积中的溶解度不同,因此氢能增强滑移定位。如果 SRO 不存在或没有明显形成,氢增加的自由电子浓度会导致塑性增强。本文介绍并解释了氢对钛β合金和奥氏体钢塑性的积极影响。
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 Reviews
Corrosion Reviews 工程技术-材料科学:膜
CiteScore
5.20
自引率
3.10%
发文量
44
审稿时长
4.5 months
期刊介绍: Corrosion Reviews is an international bimonthly journal devoted to critical reviews and, to a lesser extent, outstanding original articles that are key to advancing the understanding and application of corrosion science and engineering in the service of society. Papers may be of a theoretical, experimental or practical nature, provided that they make a significant contribution to knowledge in the field.
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