| A long-life rechargeable Al ion battery based on molten salts Y Song, S Jiao, J Tu, J Wang, Y Liu, H Jiao, X Mao, Z Guo, DJ Fray Journal of Materials Chemistry A 5 (3), 1282-1291, 2017 | 189 | 2017 |
| A rechargeable Al-ion battery: Al/molten AlCl 3–urea/graphite H Jiao, C Wang, J Tu, D Tian, S Jiao Chemical Communications 53 (15), 2331-2334, 2017 | 186 | 2017 |
| Straightforward Approach toward SiO2 Nanospheres and Their Superior Lithium Storage Performance J Tu, Y Yuan, P Zhan, H Jiao, X Wang, H Zhu, S Jiao The Journal of Physical Chemistry C 118 (14), 7357-7362, 2014 | 127 | 2014 |
| A Novel Ultrafast Rechargeable Multi-Ions Battery. S Wang, S Jiao, D Tian, HS Chen, H Jiao, J Tu, Y Liu, DN Fang Advanced Materials (Deerfield Beach, Fla.) 29 (16), 2017 | 125 | 2017 |
| Direct Conversion of Greenhouse Gas CO2 into Graphene via Molten Salts Electrolysis L Hu, Y Song, S Jiao, Y Liu, J Ge, H Jiao, J Zhu, J Wang, H Zhu, DJ Fray ChemSusChem 9 (6), 588-594, 2016 | 106 | 2016 |
| Rechargeable nickel telluride/aluminum batteries with high capacity and enhanced cycling performance Z Yu, S Jiao, J Tu, Y Luo, WL Song, H Jiao, M Wang, H Chen, D Fang ACS nano 14 (3), 3469-3476, 2020 | 86 | 2020 |
| Nonmetal Current Collectors: The Key Component for High‐Energy‐Density Aluminum Batteries LL Chen, WL Song, N Li, H Jiao, X Han, Y Luo, M Wang, H Chen, S Jiao, ... Advanced Materials 32 (42), 2001212, 2020 | 71 | 2020 |
| Gel electrolytes with a wide potential window for high-rate Al-ion batteries Z Yu, S Jiao, J Tu, WL Song, H Lei, H Jiao, H Chen, D Fang Journal of Materials Chemistry A 7 (35), 20348-20356, 2019 | 65 | 2019 |
| Electrochemical Conversion of CO2 into Negative Electrode Materials for Li‐Ion Batteries J Ge, L Hu, W Wang, H Jiao, S Jiao ChemElectroChem 2 (2), 224-230, 2015 | 63 | 2015 |
| A review on liquid metals as cathodes for molten salt/oxide electrolysis S Jiao, H Jiao, W Song, M Wang, J Tu International Journal of Minerals, Metallurgy and Materials 27, 1588-1598, 2020 | 57 | 2020 |
| The electrochemical behavior of an aluminum alloy anode for rechargeable Al-ion batteries using an AlCl 3–urea liquid electrolyte C Wang, J Li, H Jiao, J Tu, S Jiao RSC advances 7 (51), 32288-32293, 2017 | 52 | 2017 |
| A rechargeable Al–Te battery H Jiao, D Tian, S Li, C Fu, S Jiao ACS Applied Energy Materials 1 (9), 4924-4930, 2018 | 50 | 2018 |
| Sustainable recycling of titanium scraps and purity titanium production via molten salt electrolysis H Jiao, WL Song, H Chen, M Wang, S Jiao, D Fang Journal of Cleaner Production 261, 121314, 2020 | 47 | 2020 |
| Ternary AlCl3-urea-[EMIm] Cl ionic liquid electrolyte for rechargeable aluminum-ion batteries J Li, J Tu, H Jiao, C Wang, S Jiao Journal of The Electrochemical Society 164 (13), A3093, 2017 | 47 | 2017 |
| Current progresses and future prospects on aluminium–air batteries X Liu, H Jiao, M Wang, W Song, J Xue, S Jiao International Materials Reviews 67 (7), 734-764, 2022 | 46 | 2022 |
| Fe 4 [Fe (CN) 6] 3: A cathode material for sodium-ion batteries H Sun, H Sun, W Wang, H Jiao, S Jiao RSC Advances 4 (81), 42991-42995, 2014 | 46 | 2014 |
| Direct preparation of titanium alloys from Ti-bearing blast furnace slag H Jiao, D Tian, S Wang, J Zhu, S Jiao Journal of The Electrochemical Society 164 (7), D511, 2017 | 45 | 2017 |
| Direct preparation of V-Al alloy by molten salt electrolysis of soluble NaVO3 on a liquid Al cathode Y Xu, H Jiao, M Wang, S Jiao Journal of Alloys and Compounds 779, 22-29, 2019 | 44 | 2019 |
| Stable Quasi‐Solid‐State Aluminum Batteries Z Huang, WL Song, Y Liu, W Wang, M Wang, J Ge, H Jiao, S Jiao Advanced Materials 34 (8), 2104557, 2022 | 42 | 2022 |
| Aluminum‐Ion Asymmetric Supercapacitor Incorporating Carbon Nanotubes and an Ionic Liquid Electrolyte: Al/AlCl3‐[EMIm]Cl/CNTs H Jiao, J Wang, J Tu, H Lei, S Jiao Energy Technology 4 (9), 1112-1118, 2016 | 33 | 2016 |
Wei Wang (王伟)Professor, University of Science and Technology Beijing; Harvard University; Peking UniversityBestätigte E-Mail-Adresse bei g.harvard.edu