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Zirconia-engineered semiconducting LDH/MgO composites on AZ31 Mg alloy for enhanced corrosion resistance

Mosab Kaseem, Talitha Tara Thanaa, Iqra Rabani, Zahra Sangarimotlagh, Arash Fattah‐alhosseini

2025Journal of Materials Research and Technology5 citationsDOIOpen Access PDF

Abstract

This work reports the fabrication of zirconia-engineered semiconducting CoFe-layered double hydroxide (CoFe-LDH) architectures on MgO layers formed by micro-arc oxidation (MAO) of AZ31 Mg alloys for enhanced corrosion protection. Two strategies were investigated: (i) incorporation of ZrO 2 nanoparticles during MAO and (ii) post-modification of LDH layers with ZrO 2 via hydrothermal treatment. ZrO 2 incorporation during MAO produced denser MgO layers that facilitated LDH nucleation, while post-treatment effectively sealed surface defects in the LDH matrix. Electrochemical tests demonstrated remarkable improvements: the corrosion current density decreased from 1.43 × 10 -6 A·cm -2 for MAO to 7.60 × 10 -10 A·cm -2 for LDH-ZrO 2 , accompanied by significant increases in both outer- and inner-layer resistances. Mott–Schottky analysis confirmed that MAO and MAO-ZrO 2 coatings are predominantly p-type, while LDH-containing composites display dual p-/n-type behavior due to their heterogeneous layered structure. Mott–Schottky analysis further revealed that MAO and MAO-ZrO 2 coatings exhibit p-type behavior with relatively high carrier densities, while LDH-containing composites display dual p-/n-type responses due to their heterogeneous layered structure. Among these, LDH–ZrO 2 exhibited the lowest carrier density (1.102 × 10 12 cm -3 ), indicating the formation of a highly resistive electronic barrier that effectively suppresses charge transfer and chloride ingress. Density functional theory (DFT) calculations further confirmed the strong interfacial interactions between ZrO 2 particles and the LDH matrix, which contribute to enhanced structural stability and improved charge-blocking capability. Overall, zirconia-modified LDH hybrids act as compact semiconducting barriers that markedly improve magnesium alloy corrosion resistance in chloride-rich environments.

Topics & Concepts

Materials scienceCorrosionAlloyHydroxideComposite materialElectrochemistryMagnesium alloyCurrent densityNanoparticleMagnesiumResistive touchscreenChemical engineeringFabricationTransmission electron microscopyChlorideHydrothermal circulationSimulated body fluidDensity functional theoryMetallurgyComposite numberMagnesium Alloys: Properties and ApplicationsLayered Double Hydroxides Synthesis and ApplicationsCorrosion Behavior and Inhibition
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