What does this research mean for the field?

Methyltrioctylammonium chloride (MTOAC) provides superior corrosion inhibition for S275JR steel in acidic chloride environments compared to methyltriphenylphosphonium bromide (MTPB) due to its higher electronic softness, polarizability, and stronger adsorption to the Fe(110) surface. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The study aims to evaluate the corrosion inhibition effects of MTOAC and MTPB on S275JR steel in acidic chloride environments.

June 3, 2026Open Access

Corrosion Inhibition of S275JR Steel in Acid Chloride using Methyltrioctylammonium Chloride and Methyltriphenyl Phosphonium Bromide - Based Deep Eutectic Solvents as Passivation Enhancers – Density Functional Theory & Molecular Simulation Analysis

Puntos clave

The study aims to evaluate the corrosion inhibition effects of MTOAC and MTPB on S275JR steel in acidic chloride environments.
Utilized DFT optimizations for electronic property analysis and molecular dynamics simulations on Fe(110) model.
Compared electronic characteristics and adsorption capabilities of two DES components: MTOAC and MTPB.
Analyzed binding energies and adsorption trends with respect to corrosion inhibition.
MTOAC demonstrated significantly stronger adsorption with an interaction energy of approximately -220.34 kcal•mol⁻¹; MTPB's interaction energy was around -150.57 kcal•mol⁻¹.
Electronic descriptors indicated MTOAC's greater reactivity compared to MTPB, with lower HOMO and higher polarizability values.
DFT results and MD simulations showed that MTOAC provides a more stable and thicker protective layer than MTPB.

Resumen

We carried out an investigation into the use of two deep eutectic solvent (DES) components—methyltrioctylammonium chloride (MTOAC) and methyltriphenylphosphonium bromide (MTPB), as green passivation enhancers for S275JR steel in acidic chloride environments. Atomistic modelling comprising DFT (ωB97XD/6-311++G(2d,2p)) optimizations, Mulliken and Fukui analyses, non-covalent interaction (NCI) mapping, and molecular dynamics (MD) simulations on an Fe(110) model to elucidate adsorption modes and electronic drivers of inhibition was adopted. DFT descriptors showed striking electronic differences between the two inhibitors: MTOAC is electronically softer and more polarizable (EHOMO = −4.268 eV, ELUMO = −1.696 eV, ΔE = 2.572 eV, ΔN ≈ 1.56), whereas MTPB is comparatively hard and less reactive (EHOMO = −6.706 eV, ELUMO = −0.241 eV, ΔE = 6.465 eV, ΔN ≈ 0.55). MD simulations on Fe(110) produce interaction and binding energies that corroborate these trends: Fe (110)+MTOAC shows significantly stronger adsorption (Einteraction ≈ −220.34 kcal•mol⁻¹, Ebinding ≈ 220.34 kcal•mol⁻¹) than Fe (110)+MTPB (Einteraction ≈ −150.57 kcal•mol⁻¹, Ebinding ≈ 150.57 kcal•mol⁻¹), indicating a more stable, denser protective film for MTOAC.

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