A general two‐step strategy–based high‐throughput screening of single atom catalysts for nitrogen fixation C Ling, Y Ouyang, Q Li, X Bai, X Mao, A Du, J Wang Small Methods 3 (9), 1800376, 2019 | 362 | 2019 |
Understanding the roles of oxygen vacancies in hematite‐based photoelectrochemical processes Z Wang, X Mao, P Chen, M Xiao, SA Monny, S Wang, M Konarova, A Du, ... Angewandte Chemie 131 (4), 1042-1046, 2019 | 358 | 2019 |
Edge‐Rich Fe−N4 Active Sites in Defective Carbon for Oxygen Reduction Catalysis X Wang, Y Jia, X Mao, D Liu, W He, J Li, J Liu, X Yan, J Chen, L Song, ... Advanced materials 32 (16), 2000966, 2020 | 283 | 2020 |
High‐performance perovskite composite electrocatalysts enabled by controllable interface engineering X Xu, Y Pan, L Ge, Y Chen, X Mao, D Guan, M Li, Y Zhong, Z Hu, ... Small 17 (29), 2101573, 2021 | 201 | 2021 |
Controllable CO2 electrocatalytic reduction via ferroelectric switching on single atom anchored In2Se3 monolayer L Ju, X Tan, X Mao, Y Gu, S Smith, A Du, Z Chen, C Chen, L Kou Nature communications 12 (1), 5128, 2021 | 148 | 2021 |
A directional synthesis for topological defect in carbon X Wang, Y Jia, X Mao, L Zhang, D Liu, L Song, X Yan, J Chen, D Yang, ... Chem 6 (8), 2009-2023, 2020 | 148 | 2020 |
A single boron atom doped boron nitride edge as a metal-free catalyst for N 2 fixation X Mao, S Zhou, C Yan, Z Zhu, A Du Physical Chemistry Chemical Physics 21 (3), 1110-1116, 2019 | 116 | 2019 |
Ultra-dense carbon defects as highly active sites for oxygen reduction catalysis Q Wu, Y Jia, Q Liu, X Mao, Q Guo, X Yan, J Zhao, F Liu, A Du, X Yao Chem 8 (10), 2715-2733, 2022 | 98 | 2022 |
Gradient‐Concentration Design of Stable Core–Shell Nanostructure for Acidic Oxygen Reduction Electrocatalysis X Lyu, Y Jia, X Mao, D Li, G Li, L Zhuang, X Wang, D Yang, Q Wang, A Du, ... Advanced Materials 32 (32), 2003493, 2020 | 95 | 2020 |
Carbon‐anchored molybdenum oxide nanoclusters as efficient catalysts for the electrosynthesis of ammonia and urea M Sun, G Wu, J Jiang, Y Yang, A Du, L Dai, X Mao, Q Qin Angewandte Chemie 135 (19), e202301957, 2023 | 76 | 2023 |
Predicting a new class of metal-organic frameworks as efficient catalyst for bi-functional oxygen evolution/reduction reactions X Mao, C Ling, C Tang, C Yan, Z Zhu, A Du Journal of Catalysis 367, 206-211, 2018 | 66 | 2018 |
Silicon-doped graphene edges: an efficient metal-free catalyst for the reduction of CO 2 into methanol and ethanol X Mao, G Kour, L Zhang, T He, S Wang, C Yan, Z Zhu, A Du Catalysis Science & Technology 9 (23), 6800-6807, 2019 | 63 | 2019 |
Computational Design and Experimental Validation of the Optimal Bimetal-Doped SrCoO3−δ Perovskite as Solid Oxide Fuel Cell Cathode X Mao, Z Li, M Li, X Xu, C Yan, Z Zhu, A Du Journal of the American Chemical Society 143 (25), 9507-9514, 2021 | 59 | 2021 |
Computational screening of MN 4 (M= Ti–Cu) based metal organic frameworks for CO 2 reduction using the d-band centre as a descriptor X Mao, C Tang, T He, D Wijethunge, C Yan, Z Zhu, A Du Nanoscale 12 (10), 6188-6194, 2020 | 54 | 2020 |
Unveiling the dynamic active site of defective carbon-based electrocatalysts for hydrogen peroxide production Q Wu, H Zou, X Mao, J He, Y Shi, S Chen, X Yan, L Wu, C Lang, B Zhang, ... Nature Communications 14 (1), 6275, 2023 | 48 | 2023 |
Defective graphene on the transition-metal surface: formation of efficient bifunctional catalysts for oxygen evolution/reduction reactions in alkaline media X Mao, L Zhang, G Kour, S Zhou, S Wang, C Yan, Z Zhu, A Du ACS applied materials & interfaces 11 (19), 17410-17415, 2019 | 39 | 2019 |
Computational screening of single-atom alloys TM@ Ru (0001) for enhanced electrochemical nitrogen reduction reaction G Kour, X Mao, A Du Journal of Materials Chemistry A 10 (11), 6204-6215, 2022 | 38 | 2022 |
Remarkably improved oxygen evolution reaction activity of cobalt oxides by an Fe ion solution immersion process S Pan, X Mao, J Yu, L Hao, A Du, B Li Inorganic Chemistry Frontiers 7 (18), 3327-3339, 2020 | 32 | 2020 |
Computational screening of transition metal–phthalocyanines for the electrochemical reduction of carbon dioxide G Kour, X Mao, A Du The Journal of Physical Chemistry C 124 (14), 7708-7715, 2020 | 31 | 2020 |
Cuδ+ active sites stabilization through Mott-Schottky effect for promoting highly efficient conversion of carbon monoxide into n-propanol T He, G Kour, X Mao, A Du Journal of Catalysis 382, 49-56, 2020 | 30 | 2020 |