References

cpomaem

Коррозия: защита материалов и методы исследований

Title in english

ИФХЭ РАН

10.61852/2949-3412-2025-3-1-137-163

cpomaem-93

Research Article

Статьи

Влияние имидазолатного каркаса ZIF-8 на ингибирующий эффект аспартатов при атмосферной коррозии низкоуглеродистой стали

Influence of ZIF-8 on the inhibition effect of aspartates for atmospheric corrosion of mild steel

Ян

Хайни

Yang

Шанхай 201306

Ма

Лян

Шанхай 201306

Чжан

Дацюань

Zhang

Шанхай 201306

Ань

Сифэй

Шанхай 201306

Цуй

Чжэньи

Cui

Шанхай 201306

Андреев

Н. Н.

Andreev

N. N.

19071, Москва, Ленинский проспект, д.31, корп. 4

n.andreev@mail.ru

Шанхайский университет электроэнергетикиКитай

ФГБУН Институт физической химии и электрохимии им. А.Н. Фрумкина Российской академии наук (ИФХЭ РАН)Россия

2025

14042025

01137163

2025

Ян Х., Ма Л., Чжан Д., Ань С., Цуй Ч., Андреев Н.Н.

Yang H., Ma L., Zhang D., An S., Cui Z., Andreev N.N.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://www.cpmrm.ru/jour/article/view/93

Цель данного исследования – разработка нового нанокомпозитного летучего ингибитора коррозии (ZIF-AD) низкоуглеродистой стали за счет реакции между аспарагиновой кислотой и ди-н-бутиламином (AD) на цеолитном имидазолатном каркасе (zeolitic imidazolate framework-8, ZIF-8). Пористая структура ZIF-8 способствует распределению молекул аспарагиновой кислоты, уменьшая их агломерацию и повышая летучесть. Ингибирующее действие ZIF-AD в условиях окружающей среды достигается благодаря летучести этого соединения и его способности к адсорбции. Показано, что при использовании ингибитора на поверхности стали образуется защитная пленка, эффективно подавляющая катодную реакцию. Полученные результаты показывают, что ZIF-AD может потенциально использоваться в качестве высокоэффективного ингибитора коррозии низкоуглеродистой стали в атмосферных условиях.

This study aims to develop a novel volatile corrosion inhibitor for mild steel by preparing a nanocomposite (ZIF-AD) through a salt-forming reaction between aspartic acid (AD) and din-butylamine, with zeolitic imidazolate framework-8 (ZIF-8) as the template material. The ZIF-8's porous structure is beneficial to disperse AD molecules, reducing agglomeration and enhancing volatility. Under ambient atmosphere, ZIF-AD achieves corrosion inhibition properties through volatilization and adsorption. It demonstrates that a protective film is formed on mild steel surfaces, effectively inhibiting the cathodic process of corrosion. Compared to AD alone, the incorporation of ZIF-8 increased the inhibition efficiency to 91%. These findings highlight the potential of ZIF-AD as a highly efficient corrosion inhibitor for mild steel in atmospheric environments.

летучий ингибитор коррозиинизкоуглеродистая стальатмосферная коррозияаспарагиновая кислотаZIF-8

volatile corrosion inhibitormild steelatmospheric corrosionaspartic acidZIF-8electrochemical mechanism

Работа выполнена при поддержке Национального фонда естественных наук Китая (52071198) и Открытого фонда Шанхайской ведущей лаборатории защиты материалов и современных материалов в электроэнергетике, а также Министерства образования и науки РФ.

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