Corrision inhibition of an aluminum alloy in a chloride-containing environment by a composition based on dextrin and sodium isoascorbate

Keywords

dextrin, sodium isoascorbate, corrosion inhibition, aluminium alloy, electro-chemical impedance spectroscopy, energy dispersive X-ray analysis, degree of protection.

Cite as

Tymus M. B., Zin I. M., and Korniy S. A. Corrision inhibition of an aluminum alloy in a chloride-containing environment by a composition based on dextrin and sodium isoascorbate. Physicochemical Mechanics of Materials. 2024. 60(4), 129-136.

https://doi.org/10.15407/pcmm2024.04.129

Abstract

Using the methods of electrochemical impedance spectroscopy, scanning electron micro­scopy, and energy dispersive X-ray analysis, the corrosion inhibition of aluminum alloy in a neutral chloride-containing environment with a composition containing equal weight amounts of dextrin and sodium isoascorbate was investigated. An approximately 20-time increase in the charge transfer resistance of the aluminum alloy due to the protective effect of the inhibitory composition at its optimal concentration was established. A dense adsorption organic film was found on the surface of the metal in the inhibited solution. The degree of metal corrosion protection by the dextrin-isoascorbate composition exceeds 90%. The practical effect of the research is the possibility of obtaining an environment friendly inhibitory composition based on renewable plant materials for corrosion protec­tion of aluminum alloy constructions.

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