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Oxygen-vacancy engineering and junction design in CeO2 nanomaterials for photocatalysis and antibacterial action: A review

Maqusood Ahamed, Syed Mansoor Ali, Rashid Lateef, Guilherme Luiz Dotto, Hisham A. Alhadlaq

2025Results in Engineering30 citationsDOIOpen Access PDF

Abstract

Cerium oxide (CeO 2 ) nanomaterials occupy a distinctive position in environmental catalysis and antimicrobial technologies because their fluorite lattice accommodates oxygen vacancies and facile Ce 3+ /Ce 4+ redox cycling. This review synthesizes recent progress in “defect programming” and junction engineering to convert CeO 2 into high-performance platforms for solar-driven pollutant degradation and antibacterial action. We analyze how vacancy ensembles, aliovalent doping, and facet control reshape band structure, extend optical response, and modulate adsorption/activation of O 2 and H 2 O. Emphasis is placed on interfacial designs type-II heterojunctions, direct Z-/S-schemes, and Schottky contacts with metals and conductive carbons that preserve redox potentials while suppressing electron-hole recombination. Synthesis strategies (co-precipitation, hydro/solvothermal, sol–gel/Pechini, microwave/ultrasound, and green/biotemplated routes) are benchmarked for their ability to set vacancy “set-points” and achieve intimate, clean interfaces. We connect characterization toolkits (XPS/UPS, EPR, Raman, UV–Vis DRS, TRPL, EIS/IMPS) to mechanistic fingerprints of reactive oxygen species (•O 2 ⁻, •OH, ¹O 2 ) generation under realistic aqueous conditions. Device-level architectures (immobilized films, polymeric and magnetic frameworks) and reactor/photonic choices are shown to be as determinative as powder composition for durability, separability, and solar utilization. Persistent challenges include disentangling genuine semiconductor pathways from dye/matrix artifacts, stabilizing vacancies in ion-rich waters, and converging on field-relevant metrics beyond decolorization (e.g., TOC mineralization and product inventories). We outline priorities for operando-verified vacancy control, co-design of materials with optics/reactors, robust anchoring and regeneration protocols, and standardized benchmarking to translate CeO 2 -centered composites into scalable environmental remediation and antibacterial technologies.

Topics & Concepts

NanomaterialsNanotechnologyMaterials sciencePhotocatalysisVacancy defectCerium oxideEnvironmentally friendlyCeriumEnvironmental remediationSchottky barrierOxideCatalysisRedoxKirkendall effectSemiconductorBismuthNanocompositeCerium nitrateAqueous solutionNanocrystalMineralization (soil science)Catalytic Processes in Materials ScienceAdvanced Nanomaterials in CatalysisAdvanced Photocatalysis Techniques
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