| Directly converting CO2 into a gasoline fuel J Wei, Q Ge, R Yao, Z Wen, C Fang, L Guo, H Xu, J Sun Nature communications 8 (1), 15174, 2017 | 1064 | 2017 |
| Towards the development of the emerging process of CO 2 heterogenous hydrogenation into high-value unsaturated heavy hydrocarbons J Wei, R Yao, Y Han, Q Ge, J Sun Chemical Society Reviews 50 (19), 10764-10805, 2021 | 255 | 2021 |
| New insights into the effect of sodium on Fe 3 O 4-based nanocatalysts for CO 2 hydrogenation to light olefins J Wei, J Sun, Z Wen, C Fang, Q Ge, H Xu Catalysis Science & Technology 6 (13), 4786-4793, 2016 | 251 | 2016 |
| Catalytic Hydrogenation of CO2 to Isoparaffins over Fe-Based Multifunctional Catalysts J Wei, R Yao, Q Ge, Z Wen, X Ji, C Fang, J Zhang, H Xu, J Sun ACS Catalysis 8 (11), 9958-9967, 2018 | 192 | 2018 |
| Directly converting carbon dioxide to linear α-olefins on bio-promoted catalysts L Guo, J Sun, X Ji, J Wei, Z Wen, R Yao, H Xu, Q Ge Communications Chemistry 1 (1), 11, 2018 | 161 | 2018 |
| Precisely regulating Brønsted acid sites to promote the synthesis of light aromatics via CO2 hydrogenation J Wei, R Yao, Q Ge, D Xu, C Fang, J Zhang, H Xu, J Sun Applied Catalysis B: Environmental 283, 119648, 2021 | 140 | 2021 |
| Interfacing with Carbonaceous Potassium Promoters Boosts Catalytic CO2 Hydrogenation of Iron Y Han, C Fang, X Ji, J Wei, Q Ge, J Sun ACS Catalysis 10 (20), 12098-12108, 2020 | 135 | 2020 |
| Monometallic iron catalysts with synergistic Na and S for higher alcohols synthesis via CO2 hydrogenation R Yao, J Wei, Q Ge, J Xu, Y Han, Q Ma, H Xu, J Sun Applied Catalysis B: Environmental 298, 120556, 2021 | 86 | 2021 |
| Elucidating the structural evolution of highly efficient Co–Fe bimetallic catalysts for the hydrogenation of CO2 into olefins N Liu, J Wei, J Xu, Y Yu, J Yu, Y Han, K Wang, JI Orege, Q Ge, J Sun Applied Catalysis B: Environmental 328, 122476, 2023 | 52 | 2023 |
| Highly stable Sr and Na co-decorated Fe catalyst for high-valued olefin synthesis from CO2 hydrogenation JI Orege, J Wei, Y Han, M Yang, X Sun, J Zhang, CC Amoo, Q Ge, J Sun Applied Catalysis B: Environmental 316, 121640, 2022 | 46 | 2022 |
| Dynamic confinement catalysis in Fe-based CO2 hydrogenation to light olefins L Wang, Y Han, J Wei, Q Ge, S Lu, Y Mao, J Sun Applied Catalysis B: Environmental 328, 122506, 2023 | 38 | 2023 |
| Fischer–Tropsch synthesis over iron catalysts with corncob-derived promoters L Guo, J Sun, J Wei, Z Wen, H Xu, Q Ge Journal of energy chemistry 26 (4), 632-638, 2017 | 28 | 2017 |
| Structure sensitivity of iron oxide catalyst for CO2 hydrogenation R Yao, J Wei, Q Ge, J Xu, Y Han, H Xu, J Sun Catalysis Today 371, 134-141, 2021 | 25 | 2021 |
| Emerging spinel ferrite catalysts for driving CO2 hydrogenation to high-value chemicals JI Orege, GA Kifle, Y Yu, J Wei, Q Ge, J Sun Matter 6 (5), 1404-1434, 2023 | 24 | 2023 |
| Highly selective production of long-chain aldehydes, ketones or alcohols via syngas at a mild condition J Xu, J Wei, J Zhang, R Yao, Q Ge, Q Ma, J Sun Applied Catalysis B: Environment and Energy 307, 121155, 2022 | 22 | 2022 |
| Boosting CO2 hydrogenation to high-value olefins with highly stable performance over Ba and Na co-modified Fe catalyst JI Orege, N Liu, CC Amoo, J Wei, Q Ge, J Sun Journal of Energy Chemistry 80, 614-624, 2023 | 20 | 2023 |
| Spinel-structured nanocatalysts: New opportunities for CO2 hydrogenation to value-added chemicals JI Orege, J Wei, Q Ge, J Sun Nano Today 51, 101914, 2023 | 19 | 2023 |
| Isoparaffin-rich gasoline synthesis from DME over Ni-modified HZSM-5 Z Wen, C Wang, J Wei, J Sun, L Guo, Q Ge, H Xu Catalysis Science & Technology 6 (22), 8089-8097, 2016 | 17 | 2016 |
| Sputtering FeCu nanoalloys as active sites for alkane formation in CO2 hydrogenation Z Si, CC Amoo, Y Han, J Wei, J Yu, Q Ge, J Sun Journal of Energy Chemistry 70, 162-173, 2022 | 16 | 2022 |
| Precisely synergistic synthesis of higher alcohols from syngas over iron carbides J Xu, J Wei, J Zhang, N Liu, Q Ge, J Sun Chem Catalysis 3 (4), 2023 | 13 | 2023 |
