被动性
材料科学
溶解
氧化物
析氧
腐蚀
合金
金属
电化学
氧气
冶金
化学工程
电极
化学
物理化学
有机化学
电气工程
工程类
作者
Alfred Larsson,Andrea Grespi,Giuseppe Abbondanza,Josefin Eidhagen,Dorotea Gajdek,Konstantin Simonov,Xiaoqi Yue,U. Lienert,Zoltán Hegedűs,Arno Jeromin,Thomas F. Keller,Mattia Scardamaglia,Andrey Shavorskiy,Lindsay R. Merte,Jinshan Pan,Edvin Lundgren
标识
DOI:10.1002/adma.202304621
摘要
Corrosion is the main factor limiting the lifetime of metallic materials, and a fundamental understanding of the governing mechanism and surface processes is difficult to achieve since the thin oxide films at the metal-liquid interface governing passivity are notoriously challenging to study. In this work, a combination of synchrotron-based techniques and electrochemical methods is used to investigate the passive film breakdown of a Ni-Cr-Mo alloy, which is used in many industrial applications. This alloy is found to be active toward oxygen evolution reaction (OER), and the OER onset coincides with the loss of passivity and severe metal dissolution. The OER mechanism involves the oxidation of Mo4+ sites in the oxide film to Mo6+ that can be dissolved, which results in passivity breakdown. This is fundamentally different from typical transpassive breakdown of Cr-containing alloys where Cr6+ is postulated to be dissolved at high anodic potentials, which is not observed here. At high current densities, OER also leads to acidification of the solution near the surface, further triggering metal dissolution. The OER plays an important role in the mechanism of passivity breakdown of Ni-Cr-Mo alloys due to their catalytic activity, and this effect needs to be considered when studying the corrosion of catalytically active alloys.
科研通智能强力驱动
Strongly Powered by AbleSci AI