cpomaemКоррозия: защита материалов и методы исследованийTitle in englishИФХЭ РАН10.61852/2949-3412-2024-2-2-1-12cpomaem-51Research ArticleСтатьиПрименение электродугового нанесения алюминия и супергидрофобизации для защиты магниевых сплавов от коррозииApplication of electric arc deposition of aluminum and superhydrophobization to protect magnesium alloys against corrosionЕмельяненкоА. М.EmelyanenkoA. M.

Ленинский просп.31, корп. 4, Москва, 119071

Leninsky prosp. 31 bldg. 4, 119071 Moscow

ame@phyche.ac.ruЕмельяненкоК. А.EmelyanenkoK. A.

Ленинский просп.31, корп. 4, Москва, 119071

Leninsky prosp. 31 bldg. 4, 119071 Moscow

БалдаевЛ. Х.BaldaevL. Kh.

ул. Южная 9А, г. Щербинка, Москва, 108851

Yuzhnaya str. 9A, Shcherbinka, Moscow, 108851

МаньковскийС. А.Man’kovskyS. A.

ул. Южная 9А, г. Щербинка, Москва, 108851

Yuzhnaya str. 9A, Shcherbinka, Moscow, 108851

ФедороваМ. О.FedorovaM. O.

ул. Южная 9А, г. Щербинка, Москва, 108851

Yuzhnaya str. 9A, Shcherbinka, Moscow, 108851

БалдаевС. Л.BaldaevS. L.

ул. Южная 9А, г. Щербинка, Москва, 108851

Yuzhnaya str. 9A, Shcherbinka, Moscow, 108851

БойновичЛ. Б.BoinovichL. B.

Ленинский просп.31, корп. 4, Москва, 119071

Leninsky prosp. 31 bldg. 4, 119071 Moscow

Институт физической химии и электрохимии им. А.Н. Фрумкина Российской академии наук (ИФХЭ РАН)РоссияA.N. Frumkin Institute of Physical Chemistry and Electrochemistry, Russian Academy of SciencesRussian FederationООО «Технологические системы защитных покрытий» (ООО «ТСЗП»)РоссияLLC «Technological Systems of Protective Coatings» (LLC «TSPC»)Russian Federation20242506202402112Copyright © Емельяненко А.М., Емельяненко К.А., Балдаев Л.Х., Маньковский С.А., Федорова М.О., Балдаев С.Л., Бойнович Л.Б., 20242024Емельяненко А.М., Емельяненко К.А., Балдаев Л.Х., Маньковский С.А., Федорова М.О., Балдаев С.Л., Бойнович Л.Б.Emelyanenko A.M., Emelyanenko K.A., Baldaev L.K., Man’kovsky S.A., Fedorova M.O., Baldaev S.L., Boinovich L.B.This work is licensed under a Creative Commons Attribution 4.0 License.https://www.cpmrm.ru/jour/article/view/51

Эксплуатация магния и его сплавов ограничена их низкой коррозионной стойкостью. Поэтому в реальных условиях необходимо модифицировать поверхностные свойства изделий из магниевых сплавов так, чтобы остановить или существенно замедлить разрушительные коррозионные процессы. В данной работе предложен подход к получению противокоррозионных покрытий для магниевых сплавов, основанный на электродуговом нанесении слоя алюминия на поверхность магния, лазерной обработке этого слоя и последующей хемосорбции гидрофобного агента. Получающееся по предложенной технологии покрытие является супергидрофобным и характеризуется очень высокой стойкостью супергидрофобного состояния при контакте с коррозионно-активными средами. Длительные исследования покрытия на водостойкость,  устойчивость  к  солевому  туману  и  при  погружении  в хлоридсодержащий раствор показало очень высокую химическую стойкость покрытия и сохранение чрезвычайно высоких противокоррозионных свойств даже при непрерывном контакте с солевым раствором в течение 2-х месяцев. Наблюдающаяся эффективность коррозионной защиты разработанных покрытий объясняется супергидрофобным состоянием поверхности и большей химической инертностью оксида алюминия по сравнению с оксидами и гидроксидами магния.

The use of magnesium and its alloys is limited due to their low corrosion resistance. In real-world conditions, it is therefore necessary to modify the surface properties of magnesium alloy products in order to prevent or significantly slow down destructive corrosion processes. This paper proposes an approach for creating anti-corrosion coatings on magnesium alloys through the use of electric arc deposition of aluminum layer on alloy surface, laser processing of this layer, followed by chemisorption of a hydrophobic agent. The resulting coating, created using this method, is superhydrophobic and has a high level of resistance to corrosion under contact with corrosive media. Long-term studies on the coating's water resistance, salt spray resistance, and immersion in a chloride-containing solution have shown that the coating has a very high chemical resistance and retains its extremely high anti-corrosive properties even after continuous contact with saline solution for two months. The effectiveness of corrosion protection provided by the developed coatings can be explained by the superhydrophobic state of their surface and the greater chemical inertness of aluminum oxide compared to magnesium oxides and hydroxides.

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The authors declare that there are no conflicts of interest present.