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Oxygen Vacancy Formation Energy Determines the Phase-Activity Relationship of MnO<sub>2</sub> Laccase Nanozymes

Qing Tian, Haoyu Wang, Shuaiqi Huangfu, Rong Yang, Yao Chen, Jie Gao, Yingchun Yang, Lianbing Zhang

2025ACS Applied Materials & Interfaces15 citationsDOI

Abstract

Although manganese dioxide (MnO 2 ) has been explored as a powerful laccase nanozyme for pollutant oxidation in wastewater treatment, the phase-activity relationship of multiphase MnO 2 remains ambiguous and controversial. Herein, the experimental studies show that the laccase-like activities and aerobic catalytic oxidation toward tetracycline antibiotics of the six types of MnO 2 are in the following order: β- > λ- > γ- > α- > ε- > δ-MnO 2 . Density functional theory (DFT) calculations revealed that the catalytic activities are inversely proportional to the oxygen vacancy formation energies of the different MnO 2 materials. Further investigation of surface oxygen species with reactivity demonstrated that rich oxygen vacancies boost the oxygen mobility and catalytic efficiency of MnO 2 nanozymes, which is in good agreement with both experimental and DFT results. Hence, this study reveals the decisive role of the crystal phase in the oxygen vacancy generation, which elucidates the laccase-like catalytic mechanism of MnO 2 nanozymes and is valuable for the future design and synthesis of MnO 2 nanocatalysts.

Topics & Concepts

CatalysisMaterials scienceManganeseLaccaseDensity functional theoryNanomaterial-based catalystVacancy defectOxygenPhase (matter)Reactivity (psychology)Chemical physicsInorganic chemistryChemical engineeringNanotechnologyChemistryComputational chemistryNanoparticleCrystallographyOrganic chemistryMetallurgyEnzymePathologyEngineeringAlternative medicineMedicineAdvanced Nanomaterials in CatalysisElectrochemical sensors and biosensorsNanocluster Synthesis and Applications
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