| City-level climate change mitigation in China Y Shan, D Guan, K Hubacek, B Zheng, SJ Davis, L Jia, J Liu, Z Liu, ... Science advances 4 (6), eaaq0390, 2018 | 360 | 2018 |
| Pristine carbon nanotubes as non-metal electrocatalysts for oxygen evolution reaction of water splitting Y Cheng, C Xu, L Jia, JD Gale, L Zhang, C Liu, PK Shen Applied Catalysis B: Environmental 163, 96-104, 2015 | 169 | 2015 |
| LaMnO3-based perovskite with in-situ exsolved Ni nanoparticles: a highly active, performance stable and coking resistant catalyst for CO2 dry reforming of CH4 T Wei, L Jia, H Zheng, B Chi, J Pu, J Li Applied Catalysis A: General 564, 199-207, 2018 | 111 | 2018 |
| Theoretical study on the electronic and optical properties of (N, Fe)-codoped anatase TiO2 photocatalyst L Jia, C Wu, S Han, N Yao, Y Li, Z Li, B Chi, J Pu, L Jian Journal of Alloys and Compounds 509 (20), 6067-6071, 2011 | 110 | 2011 |
| A novel layered perovskite Nd (Ba0. 4Sr0. 4Ca0. 2) Co1. 6Fe0. 4O5+ δ as cathode for proton-conducting solid oxide fuel cells J Chen, J Li, L Jia, I Moussa, B Chi, J Pu, J Li Journal of Power Sources 428, 13-19, 2019 | 90 | 2019 |
| Structurally controlled ZnO/TiO2 heterostructures as efficient photocatalysts for hydrogen generation from water without noble metals: The role of microporous amorphous … S Guo, S Han, H Mao, S Dong, C Wu, L Jia, B Chi, J Pu, J Li Journal of Power Sources 245, 979-985, 2014 | 88 | 2014 |
| CO2 dry reforming of CH4 with Sr and Ni co-doped LaCrO3 perovskite catalysts T Wei, L Jia, JL Luo, B Chi, J Pu, J Li Applied Surface Science 506, 144699, 2020 | 86 | 2020 |
| Redox-reversible electrode material for direct hydrocarbon solid oxide fuel cells P Qiu, X Yang, W Wang, T Wei, Y Lu, J Lin, Z Yuan, L Jia, J Li, F Chen ACS applied materials & interfaces 12 (12), 13988-13995, 2020 | 73 | 2020 |
| Enhanced visible-light photocatalytic activity of anatase TiO2 through N and S codoping L Jia, C Wu, Y Li, S Han, Z Li, B Chi, J Pu, L Jian Applied Physics Letters 98 (21), 2011 | 73 | 2011 |
| Degradation analysis and durability improvement for SOFC 1-cell stack D Yan, C Zhang, L Liang, K Li, L Jia, J Pu, L Jian, X Li, T Zhang Applied energy 175, 414-420, 2016 | 69 | 2016 |
| Materials of solid oxide electrolysis cells for H2O and CO2 electrolysis: A review. P Qiu, C Li, B Liu, D Yan, J Li, L Jia Journal of Advanced Ceramics 12 (8), 2023 | 67 | 2023 |
| A review on anode on-cell catalyst reforming layer for direct methane solid oxide fuel cells P Qiu, S Sun, X Yang, F Chen, C Xiong, L Jia, J Li International Journal of Hydrogen Energy 46 (49), 25208-25224, 2021 | 65 | 2021 |
| Preparation and properties of PrBa0. 5Sr0. 5Co1. 5Fe0. 5O5+ δ as novel oxygen electrode for reversible solid oxide electrochemical cell Y Tian, J Li, Y Liu, J Yang, B Liu, L Jia, J Jiang, B Chi, J Pu, J Li International Journal of Hydrogen Energy 43 (28), 12603-12609, 2018 | 65 | 2018 |
| A self-recovering robust electrode for highly efficient CO 2 electrolysis in symmetrical solid oxide electrolysis cells Y Tian, L Zhang, Y Liu, L Jia, J Yang, B Chi, J Pu, J Li Journal of Materials Chemistry A 7 (11), 6395-6400, 2019 | 62 | 2019 |
| Efficient and durable ammonia power generation by symmetric flat-tube solid oxide fuel cells Y Wang, Y Gu, H Zhang, J Yang, J Wang, W Guan, J Chen, B Chi, L Jia, ... Applied Energy 270, 115185, 2020 | 61 | 2020 |
| Sulfonated poly (arylene ether) s based proton exchange membranes for fuel cells M Xu, H Xue, Q Wang, L Jia International Journal of Hydrogen Energy 46 (62), 31727-31753, 2021 | 59 | 2021 |
| High-performance La0. 5 (Ba0. 75Ca0. 25) 0.5 Co0. 8Fe0. 2O3-δ cathode for proton-conducting solid oxide fuel cells D Xie, K Li, J Yang, D Yan, L Jia, B Chi, J Pu, J Li International Journal of Hydrogen Energy 46 (15), 10007-10014, 2021 | 59 | 2021 |
| High performance and stability of double perovskite-type oxide NdBa0. 5Ca0. 5Co1. 5Fe0. 5O5+ δ as an oxygen electrode for reversible solid oxide electrochemical cell Y Tian, Y Liu, W Wang, L Jia, J Pu, B Chi, J Li Journal of Energy Chemistry 43, 108-115, 2020 | 59 | 2020 |
| High-performance direct carbon dioxide-methane solid oxide fuel cell with a structure-engineered double-layer anode T Wei, P Qiu, J Yang, L Jia, B Chi, J Pu, J Li Journal of Power Sources 484, 229199, 2021 | 57 | 2021 |
| A novel PrBaCo2O5+ σ-BaZr0. 1Ce0. 7Y0. 1Yb0. 1O3 composite cathode for proton-conducting solid oxide fuel cells B Liu, L Jia, B Chi, J Pu, J Li Composites Part B: Engineering 191, 107936, 2020 | 57 | 2020 |