Corrosion inhibition by carboxylic acids—an overview

Prabha, A. Suriya; Gayathri, P.; Keerthana, R.; Nandhini, G.; Devi, N. Renuga; Dhanalakshmi, R.; Rajendran, Susai; Kumaran, S.

doi:10.1016/b978-0-323-85405-4.00010-0

Cited by 2 publications

(1 citation statement)

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“…[11] Anions in general, and carboxylate anions specifically, can also have complex effects on the rate and mechanism of metal corrosion. Carboxylic acids have been extensively studied as both promoters and inhibitors of metallic corrosion, [12] and have been used to drive metal-organic framework (MOF) synthesis via anodic dissolution/ corrosion. [13] In corrosion inhibition, inhibitor molecules adsorb on the metal surface i.e., on aluminum alloys, to form a thin protective layer of metal-inhibitor complex.…”

Section: Introductionmentioning

confidence: 99%

pKa as a Predictive Descriptor for Electrochemical Anion Adsorption

Hasan,

McCrum

2024

Angewandte Chemie

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The adsorption of anions onto metal surfaces is important in many applications including effective (electro)catalyst design, metal surface modification, and contaminant removal in wastewater treatment. In electrocatalysis, anions can be both reactive intermediates or site‐blocking spectators, where their adsorption strength therefore dictates the rate of reaction. In this work, we have measured the adsorption energy of a series of carboxylic acids on a Pt (111) single‐crystal electrode surface from aqueous solution. We find that the adsorption strength of the carboxylate anion is linearly correlated with its acid‐dissociation constant (pKa) and therefore the heterolytic O‐H bond dissociation strength in solution. Using density functional theory modeling, we split the anion adsorption energy into a sum of the adsorption energy and electron affinity of a neutral (carboxyl) radical. Surprisingly, the adsorption energy of the carboxyl radicals are similar and therefore the large difference in electron affinity is what dictates anion adsorption strength; the greater the cost in energy to remove the electron from the anion upon adsorption, the weaker its binding. Therefore, at least within a class of anions with similar structure and surface binding atoms, both electron affinity and acidity are predictive descriptors of adsorption strength.

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Section: Introductionmentioning

confidence: 99%