Nitride layers on uranium surfaces

IF 8.7 2区 工程技术 Q1 CHEMISTRY, PHYSICAL Progress in Surface Science Pub Date : 2018-08-01 DOI:10.1016/j.progsurf.2018.08.002
Kezhao Liu , Xiaofang Wang , Jing Liu , Yin Hu , Huoping Zhong , Qifa Pan , Lizhu Luo , Shouchuang Chen , Yongbin Zhang , Zhong Long
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引用次数: 20

Abstract

Uranium as an important energy material plays a significant role within the field of material sciences and nuclear industrial applications. However, metallic uranium is chemically active in ambient environment and is easily oxidized and corroded, leading to not only deterioration of its properties and failure of performance as working components but also nuclear pollution of the environment. Therefore, the development of corrosion protection systems for metallic uranium is an issue of prime importance. In view of the nitridation technology in Ti and Fe-based alloys, the successful application to improve the surface wear hardness and corrosion resistance, several nitridation methods have been developed for the surface modification of metallic uranium. Many studies have shown that the surface nitridation of metallic uranium can efficiently improve its corrosion resistance. The surface oxidation layer thickness is as thin as several nanometers even if placed 4 years in the atmosphere. At the present, nitridation of uranium surface is considered as the most promising surface modification way to protect uranium from corrosion. To design and fabricate nitride layers on uranium surface with reliable long-term protective effects, however, one needs deep understanding on the relationships among the physical and chemical properties of the nitride layers, the composition and structure of the layers, and the dependence on the techniques and the processing parameters. One also needs deep understanding on the corrosion behavior of the prepared nitride layers in the environment, and the related corrosion mechanism.

In this review, we bring to the readers the achievements and recent advances on the uranium nitridation in the world, including the processing techniques and the related studies on the formation mechanism of the nitride layers, and the understanding on the property-processing-corrosion performance relationship of the layers, aiming at the development of high-performance resistance layers for metallic uranium by the surface nitridation technique. In the review (1) the surface nitridation techniques developed recently, the relationship between the preparation parameters and the composition as well as the structure of the surface layer are summarized; (2) the fundamental physical properties of the uranium nitrides are summarized, depicted and discussed; (3) the influence of the nitrides structure and composition and of the environment on resistance to corrosion as well as the formation mechanism of corroded products in oxidizing environments are depicted and discussed; (4) the potential application of uranium nitrides in other application field such as the application of thermal-electrical conversion is also discussed. Finally, the prospective on the investigations of nitride layers is suggested.

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铀表面的氮化物层
铀作为一种重要的能源材料,在材料科学和核工业应用领域发挥着重要作用。然而,金属铀在环境中具有化学活性,易被氧化和腐蚀,不仅导致其性能恶化和工作部件性能失效,而且对环境造成核污染。因此,开发金属铀的腐蚀防护系统是一个至关重要的问题。鉴于氮化技术在Ti和fe基合金中的成功应用,提高了金属铀的表面磨损硬度和耐蚀性,开发了几种氮化方法用于金属铀的表面改性。许多研究表明,金属铀的表面氮化可以有效地提高其耐蚀性。即使在大气中放置4 年,表面氧化层厚度也只有几纳米薄。目前,铀表面氮化处理被认为是最有前途的防止铀腐蚀的表面改性方法。然而,要在铀表面设计和制造具有可靠的长期保护作用的氮化层,需要深入了解氮化层的物理化学性质与氮化层的组成和结构之间的关系,以及对技术和工艺参数的依赖性。还需要深入了解所制备的氮化物层在环境中的腐蚀行为及其腐蚀机理。本文综述了国内外在铀氮化方面取得的成就和最新进展,包括氮化层的加工技术和形成机理的相关研究,以及对氮化层性能-加工-腐蚀性能关系的认识,旨在利用表面氮化技术开发高性能金属铀电阻层。(1)综述了近年来国内外表面氮化技术的研究进展,综述了制备工艺参数与表面氮化层的组成及结构之间的关系;(2)总结、描述和讨论了氮化铀的基本物理性质;(3)描述和讨论了氮化物的结构、组成和环境对耐蚀性的影响,以及氧化环境中腐蚀产物的形成机理;(4)讨论了氮化铀在热电转换等其他应用领域的潜在应用。最后,对氮化层的研究进行了展望。
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来源期刊
Progress in Surface Science
Progress in Surface Science 工程技术-物理:凝聚态物理
CiteScore
11.30
自引率
0.00%
发文量
10
审稿时长
3 months
期刊介绍: Progress in Surface Science publishes progress reports and review articles by invited authors of international stature. The papers are aimed at surface scientists and cover various aspects of surface science. Papers in the new section Progress Highlights, are more concise and general at the same time, and are aimed at all scientists. Because of the transdisciplinary nature of surface science, topics are chosen for their timeliness from across the wide spectrum of scientific and engineering subjects. The journal strives to promote the exchange of ideas between surface scientists in the various areas. Authors are encouraged to write articles that are of relevance and interest to both established surface scientists and newcomers in the field.
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