Paper Publications

• [1]  王泽翔. Boosting photocatalytic reduction of low-concentration CO2 to CO via hydrophilic/CO2-philic interface microenvironment engineering in Ag/TiO2-x Schottky junctions.  Applied Catalysis B: Environmental,  2026. 
• [2]  王静. High-throughput screening of MIMII-PC6 dual-atom electrocatalysts for efficient and selective electrocatalytic reduction of CO2 to C1 and C2 products.  MATERIALS TODAY PHYSICS,  50,  2024. 
• [3]  王泽翔. Dual-S-scheme 0D/2D heterojunction of CsPbBr3/Agi-TiO2 for improved photocatalytic CO2 reduction: Enabling ultrafast interfacial charge transfer and product selective regulation.  Journal of Catalysis,  2025. 
• [4]  王静. High-throughput screening of MIMII-PC6 dual-atom electrocatalysts for efficient and selective electrocatalytic reduction of CO2 to C1 and C2 products.  MATERIALS TODAY PHYSICS,  2025. 
• [5]  郑茗月. Maximizing the synergistic effect of PdAu catalysts on TiO2(101) for robust CO(2 )reduction: A DFT study.  Applied Surface Science,  563,  2021. 
• [6]  孔玥琪. Enhanced photoelectrochemical performance of tungsten oxide film by bifunctional Au nanoparticles.  RSC advances,  15201, 2017. 
• [7]  王静. Tailoring the Superatomic Characteristics and Optical Behavior of Metal-Free Boron Clusters via Ligand Engineering.  JOURNAL OF PHYSICAL CHEMISTRY A,  2024. 
• [8]  王静. Trade-Off between the Coordination Environment and Active-Site Density on Fe-NxCy-C Catalysts for Enhanced Electrochemical CO2 Reduction to CO.  ACS Catal.,  13,  15794-15810, 2023. 
• [9]  焦娇娇. g-C3N4-based homojunction induced by Ag and P selective doping for improved photocatalytic H2 evolution coupled with tetracycline degradation: Type-II versus S-scheme mechanism.  Applied Surface Science,  639,  2023. 
• [10]  宋新宇. Synthesis of Cu(OH)2 nanowires at aqueous-organic interfaces.  journal of physical chemistry B,  108,  5200-5205, 2004. 
• [11]  樊唯镏. Zn2GeO4x/ZnS heterojunctions fabricated via in situ etching sulfurization for Pt-free photocatalytic hydrogen evolution: interface roughness and defect engineering.  Physical Chemistry Chemical Physics,  2020. 
• [12]  李泽坤. Synergistic engineering of architecture and composition in Ni:XCo1-xMoO4@CoMoO4 nanobrush arrays towards efficient overall water splitting electrocatalysis.  Nanoscale,  11,  22820-22831, 2019. 
• [13]  郑茗月. Oxygen vacancy and nitrogen doping collaboratively boost performance and stability of TiO2-supported Pd catalysts for CO2 photoreduction: a DFT study.  Physical chemistry chemical physics,  23,  24801-24813, 2021. 
• [14]  王泽翔. Shell-core MnO2/Carbon@Carbon nanotubes synthesized by a facile one-pot method for peroxymonosulfate oxidation of tetracycline.  Separation and Purification Technology,  278,  2022. 
• [15]  王静. Structure-Performance Descriptors and the Role of the Axial Oxygen Atom on M-N4-C Single-Atom Catalysts for Electrochemical CO2Reduction.  ACS Catal.,  12,  5441-5454, 2022.