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使用扫描微电化学技术对涂层金属切割边缘腐蚀过程进行更真实表征的贡献,以不同涂层密度的ZnAlMg镀锌钢为例说明

Contributions to a More Realistic Characterization of Corrosion Processes on Cut Edges of Coated Metals Using Scanning Microelectrochemical Techniques, Illustrated by the Case of ZnAlMg-Galvanized Steel with Different Coating Densities.

作者信息

Bolsanello Marilia Fernandes, Abreu García Andrea, da Cruz Lima Luciana Xavier, Neto Bruno Kneipel, Ferreira Jetson Lemos, Rossi Jesualdo Luiz, Costa Isolda, Souto Ricardo M, Izquierdo Javier

机构信息

Instituto de Pesquisas Energéticas e Nucleares, IPEN/CNEN-SP, São Paulo 05508-000, SP, Brazil.

Department of Chemistry, Universidad de La Laguna, 38200 La Laguna, Spain.

出版信息

Materials (Basel). 2024 Apr 5;17(7):1679. doi: 10.3390/ma17071679.

DOI:10.3390/ma17071679
PMID:38612191
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11012753/
Abstract

Corrosion processes at cut edges of galvanized steels proceed as highly localized electrochemical reactions between the exposed bulk steel matrix and the protective thin metallic coating of a more electrochemically active material. Scanning microelectrochemical techniques can thus provide the spatially resolved information needed to assess the corrosion initiation and propagation phenomena, yet most methods scan cut edge sections as embedded in insulating resin to achieve a flat surface for scanning purposes. In this work, the galvanized coatings on both sides of the material were concomitantly exposed to simulated acid rain while characterizing the cut edge response using SECM and SVET techniques, thereby maintaining the coupled effects through the exposure of the whole system as rather realistic operation conditions. The cut edges were shown to strongly promote oxygen consumption and subsequent alkalization to pH 10-11 over the iron, while diffusion phenomena eventually yielded the complete depletion of oxygen and pH neutralization of the nearby electrolyte. In addition, the cathodic activation of the exposed iron was intensified with a thinner coating despite the lower presence of sacrificial anode, and preferential sites of the attack in the corners revealed highly localized acidification below pH 4, which sustained hydrogen evolution at spots of the steel-coating interface.

摘要

镀锌钢切割边缘的腐蚀过程是在暴露的基体钢与电化学活性更高的金属保护薄涂层之间进行的高度局部化的电化学反应。扫描微电化学技术因此可以提供评估腐蚀起始和传播现象所需的空间分辨信息,然而大多数方法将切割边缘部分嵌入绝缘树脂中进行扫描,以获得用于扫描目的的平整表面。在这项工作中,材料两侧的镀锌涂层同时暴露于模拟酸雨环境中,同时使用扫描电化学显微镜(SECM)和扫描振动电极技术(SVET)表征切割边缘的响应,从而通过将整个系统暴露在更实际的运行条件下,保持耦合效应。结果表明,切割边缘强烈促进铁表面的氧气消耗以及随后碱化至pH值10 - 11,而扩散现象最终导致氧气完全耗尽以及附近电解液的pH值中和。此外,尽管牺牲阳极的存在较少,但涂层较薄时,暴露铁的阴极活化作用增强,并且在角落处的优先腐蚀部位显示出pH值低于4的高度局部酸化,这使得钢 - 涂层界面处的点持续析氢。

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Atmospheric corrosion and impact toughness of steels: Case study in steels with and without galvanizing, exposed for 3 years in Rapa Nui Island.
钢的大气腐蚀与冲击韧性:对在复活节岛暴露3年的镀锌和未镀锌钢的案例研究。
Heliyon. 2023 Jun 29;9(7):e17811. doi: 10.1016/j.heliyon.2023.e17811. eCollection 2023 Jul.
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Anti-Corrosion Reinforcements Using Coating Technologies-A Review.使用涂层技术的防腐增强措施——综述
Polymers (Basel). 2022 Nov 7;14(21):4782. doi: 10.3390/polym14214782.
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