[1]In situ formation of cocatalytic sites boosts single-atom catalysts for nitrogen oxide reduction

[2]Single cobalt atoms anchored on Ti3C2Tx with dual reaction sites for efficient adsorption–degradation of antibiotic resistance genes

[3]Superexchange-induced Pt-O-Ti3+ site on single photocatalyst for efficient H2 production with organics degradation in wastewater

[4]Dynamic active-site induced by host-guest interactions boost the Fenton-like reaction for organic wastewater treatment

[5]Enhanced Interfacial Electron Transfer by Asymmetric Cu-Ov-In Sites on In2O3 for Efficient Peroxymonosulfate Activation

[6]Selective Photoreforming of Waste Plastics into Diesel Olefins via Single Reactive Oxygen Species

[7]From Plastic Waste to Treasure: Selective Upcycling through Catalytic Technologies

[8]Enhancement of Pt-O Synergistic Sites through Titanium Vacancies for Low-Temperature Nitrogen Oxide Reduction

[9]In-situ formation of carbon-doped cerium-zirconium solid solution as a superacid catalyst for the removal of NOx

[10]Highly Efficient Peroxymonosulfate Activation on Electron-Enriched Ruthenium Dual-Atom Sites Catalysts for Enhanced Water Purification

[11]In situ synthesized S-type heterojunction Bi2O2CO3/CuBi2O4 enable efficient NIR light-driven H2O2 activation for water purification

[12]Reducing the poisoning effect of adsorbed alkaline earth metal on Nb active sites with sulfates for NH3-SCR

[13]N, S, and Cl tri-doped carbon boost the switching of radical to non-radical pathway in Fenton-like reactions: Synergism of N species and defects

[14]Photothermal synergistic effect of Ti3C2Tx/ZnIn2S4 Schottky junction for efficient inactivation of antibiotic-resistant bacteria and genes: Mechanism discussion and practical application

[15]Molecular level removal of antibiotic resistant bacteria and genes: A review of interfacial chemical in advanced oxidation processes

[16]Crittenden J.C. “Mechanistic insights for efficient inactivation of antibiotic resistance genes: a synergistic interfacial adsorption and photocatalytic-oxidation process

[17]Atomic insights for optimum and excess doping in photocatalysis: a case study of few-layer Cu-ZnIn2S4

[18]Pt-Cu Interaction induced construction of single Pt sites for synchronous electron capture and transfer in photocatalysis

[19]3D Graphene-based macrostructures for water treatment

[20]Identification the stable Pt single sites in the environment of ions: from mechanism to design principle

[21]Boosting the activation of molecular oxygen and the degradation of tetracycline over high loading Ag single atomic catalyst

[22]Efficient fenton-like process for pollutant removal in electron-rich/poor reaction sites induced by surface oxygen vacancy over cobalt-zinc oxides

[23]Accelerating FeIII-aqua complex reduction in an efficient solid-liquid-interfacial fenton reaction over the Mn-CNH Co-catalyst at near-neutral pH

[24]Facilitating redox cycles of copper species by pollutants in peroxymonosulfate activation

[25]The role of alkali metal in α-MnO2 catalyzed ammonia-selective catalysis

[26]Unraveling the interfacial charge migration pathway at the atomic level in a highly efficient Z-scheme photocatalyst

[27]Unravelling the synergy between oxygen vacancies and oxygen substitution in BiO2-x for efficient molecular-oxygen activation

[28]Regulating local electron density of iron single sites by introducing nitrogen vacancies for efficient photo-fenton process

[29]Almost 100 % peroxymonosulfate conversion to singlet oxygen on single-atom CoN2+2 Sites

[30]Pauling-type adsorption of O2 induced electrocatalytic singlet oxygen production on N-CuO for organic pollutants degradation

[31]Enhanced localized dipole of Pt-Au single-site catalyst for solar water splitting

[32]Tailoring of electronic and surface structures boosts exciton-triggering photocatalysis for singlet oxygen generation

[33]In situ visualizing reveals potential drive of lattice expansion on defective support toward efficient removal of nitrogen oxides

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