Electron Donor-Induced Electrochemical Reduction in Vanadate Anions to Enhance the Electrochemical Performance of Plasma Electrolytic Oxidation Layers

Metals Pub Date : 2024-05-21 DOI:10.3390/met14060606

M. Kaseem, A. Fattah‐alhosseini, Burak Dikici

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Abstract

Despite the increasing interest in enhancing the electrochemical stability of Al alloys through protective coatings, the role of electron donor agents during coating formation remains poorly understood in terms of morphological control and anticorrosion properties in aqueous environments. In this context, 1H-Benzotriazole (BTA) was utilized as a proof of concept to regulate the in situ reactive integration of V2O5 into the alumina layer via the plasma electrolytic oxidation of a 6061 Al alloy. BTA played a crucial role in chemically incorporating V2O5 into the alumina coating by supplying electrons to VO3− ions, facilitating their reduction. The quantity of BTA added to the electrolyte was found to influence defect morphology and concurrently enhance the chemical incorporation of V2O5. Notably, corrosion measurements revealed that the less porous hybrid film formed with higher corrosion resistance was associated with the utilization of increased concentrations of BTA. These findings highlight the potential of BTA in modifying the structure and improving the ability of alumina coatings to resist corrosion, enabling advanced applications in protecting Al alloys from corrosion.

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电子供体诱导钒酸根阴离子电化学还原以提高等离子电解氧化层的电化学性能

尽管人们对通过保护涂层提高铝合金电化学稳定性的兴趣与日俱增，但对于电子供体在涂层形成过程中的作用，以及在水环境中的形态控制和防腐特性，仍然知之甚少。在此背景下，我们利用 1H-苯并三唑（BTA）作为概念验证，通过对 6061 铝合金进行等离子电解氧化，调节 V2O5 与氧化铝层的原位反应整合。BTA 通过向 VO3- 离子提供电子，促进其还原，从而在将 V2O5 化学融入氧化铝涂层方面发挥了关键作用。研究发现，添加到电解液中的 BTA 数量会影响缺陷形态，同时增强 V2O5 的化学结合。值得注意的是，腐蚀测量结果表明，随着 BTA 浓度的增加，形成的杂化薄膜孔隙更少，耐腐蚀性更高。这些发现凸显了 BTA 在改变氧化铝涂层结构和提高其抗腐蚀能力方面的潜力，从而使保护铝合金免受腐蚀的先进应用成为可能。

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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Metals

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