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Quantum chemical calculations, molecular dynamic (MD) simulations and experimental studies of using some azo dyes as corrosion inhibitors for iron. Part 2: Bis–azo dye derivatives

2018; Elsevier BV; Volume: 1163; Linguagem: Inglês

10.1016/j.molstruc.2018.03.013

1872-8014

Loutfy H. Madkour, Savaş Kaya, Lei Guo, Cemal Kaya,

Synthesis of Tetrazole Derivatives

The adsorption behavior and inhibition mechanism of five synthesized bis-azo dye (BAD) derivatives on the corrosion of iron in aerated HNO3 and NaOH were investigated by performing potentiostatic polarization, weight loss (WL), thermometric and UV–visible spectra measurements. DFT calculations is applied to study the correlation between corrosion inhibition and global reactivity descriptors such as: EHOMO, ELUMO, molecular gap (ΔE), the dipole moment (μ), the global hardness (η), softness(S), electronegativity (χ), proton affinity (PA), electrophilicity (ω), nucleophilicity (ɛ), electrons transferred from inhibitors to metal surface (ΔN), initial molecule-metal interaction energy (Δψ), total electronic energy (E) and the energy change during electronic back-donation process (ΔE b-d). To mimic the real environment of corrosion inhibition, molecular dynamic (MD) simulations in aqueous phase have also been modelled consisting of all concerned species (inhibitor molecule, H2O, H3O+ ion, NO3− ion, OH− and Fe surface). The results confirmed that BAD molecules inhibit iron by adsorption behavior through donating and accepting electrons together with the formation of [Fe (II) and Fe (III)—BAD] chelate complex compounds. BAD's behavior is mainly chemisorption with some physisorption obeyed Frumkin and that of El-Awady adsorption isotherm. Kinetic parameters such as: (Kb, 1/y, Kads, f, ΔG°ads) have been determined and discussed. Binding energies of BAD molecules on Fe (110) surface followed the order: BAD_ 2 > BAD_ 1 > BAD_ 3 > BAD_ 4 > BAD_ 5. Theoretical results were found to be consistent with the experimental data reported. Our results provide important atomic/molecular insights into the anticorrosive mechanism of inhibitor molecules, which could help in understanding the organic-metal interface and designing more appropriate organic corrosion inhibitors.