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High-Density Single-Atomic Mn–N–C Site in Hierarchical Porous Biochar for Superoxide Radical-Dominated Ozonation

Jun Wang, Xiaomei Liu, Xiangyu You, Di Wu, Chengbo Ma, Ning Li, Yang Li, Xiaobin Fan, Fengbao Zhang, Wenchao Peng

2023Chemistry of Materials21 citationsDOI

Abstract

In this work, biomass-derived single-atomic (Mn–N–C) materials with hierarchical porous structures are synthesized through a double-anchoring strategy. Expandable biomass of semen sterculia lychnopherae is used with strong adsorption ability for Mn precursors. High contents of atomic Mn (7.8 wt %) is bonded with astonishing doped N (20.74 at %) to form pyridinic-type Mn–N 4 coordination. For ozonation, 100% of 50 ppm 4-nitrophenol could be rapidly degraded within 30 min with negligible Mn leaching (∼0.04 mg/L), better than lots of commercial MnO x catalysts. Compared with nitrogen-doped biomass carbon (BNC), introduction of atomic Mn will convert the dominated reactive oxidation species (ROSs) from · OH into O 2 · – with longer lifespans. According to DFT calculations, O 3 will be first adsorbed on the catalyst to form Mn–N 4 –O* ad intermediate, which will react with H 2 O to generate · OH on BNC and react with dissolved O 3 to produce O 2 · – on the Mn–N 4 sites, thus revealing a different O 3 activation mechanism on Mn–N–C catalysts.

Topics & Concepts

CatalysisBiocharLeaching (pedology)ChemistryAdsorptionCarbon fibersHydroxyl radicalInorganic chemistryChemical engineeringPyrolysisMaterials scienceRadicalPhysical chemistryOrganic chemistrySoil scienceComposite numberSoil waterEnvironmental scienceEngineeringComposite materialCatalytic Processes in Materials ScienceAdvanced Photocatalysis TechniquesAdvanced battery technologies research
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