A promising physical method for recovery of LiCoO2 and graphite from spent lithium-ion batteries: Grinding flotation J Yu, Y He, Z Ge, H Li, W Xie, S Wang Separation and Purification Technology 190, 45-52, 2018 | 218 | 2018 |
The molecular structure of Inner Mongolia lignite utilizing XRD, solid state 13C NMR, HRTEM and XPS techniques J Wang, Y He, H Li, J Yu, W Xie, H Wei Fuel 203, 764-773, 2017 | 128 | 2017 |
High-value utilization of graphite electrodes in spent lithium-ion batteries: From 3D waste graphite to 2D graphene oxide J Yu, M Lin, Q Tan, J Li Journal of Hazardous Materials 401, 123715, 2021 | 95 | 2021 |
Effect of the secondary product of semi-solid phase Fenton on the flotability of electrode material from spent lithium-ion battery J Yu, Y He, H Li, W Xie, T Zhang Powder technology 315, 139-146, 2017 | 71 | 2017 |
A global perspective on e-waste recycling K Liu, Q Tan, J Yu, M Wang Circular Economy 2 (1), 100028, 2023 | 70 | 2023 |
Exploring a green route for recycling spent lithium-ion batteries: Revealing and solving deep screening problem J Yu, Q Tan, J Li Journal of cleaner production 255, 120269, 2020 | 38 | 2020 |
Exploring the critical role of grinding modification on the flotation recovery of electrode materials from spent lithium ion batteries J Yu, Y He, L Qu, J Yang, W Xie, X Zhu Journal of cleaner production 274, 123066, 2020 | 36 | 2020 |
Challenges in recycling spent lithium‐ion batteries: spotlight on polyvinylidene fluoride removal M Wang, K Liu, J Yu, Q Zhang, Y Zhang, M Valix, DCW Tsang Global Challenges 7 (3), 2200237, 2023 | 31 | 2023 |
In-situ enhanced catalytic reforming behavior of cobalt-based materials with inherent zero-valent aluminum in spent lithium ion batteries J Yu, S Zou, G Xu, L Liu, M Zhao, J Li Applied Catalysis B: Environmental 303, 120920, 2022 | 22 | 2022 |
Recycling spent lithium-ion batteries using a mechanochemical approach M Wang, K Liu, J Yu, CC Zhang, Z Zhang, Q Tan Circular Economy 1 (2), 100012, 2022 | 21 | 2022 |
Unveiling sodium ion pollution in spray-dried precursors and its implications for the green upcycling of spent lithium-ion batteries J Yu, Y Liu, S Han, Q Tan, L Liu, J Li Environmental Science & Technology 55 (21), 14897-14905, 2021 | 18 | 2021 |
Mechanochemical upcycling of spent LiCoO2 to new LiNi0.80Co0.15Al0.05O2 battery: An atom economy strategy J Yu, J Li, S Zhang, F Wei, Y Liu, J Li Proceedings of the National Academy of Sciences 120 (14), e2217698120, 2023 | 17 | 2023 |
Advancing recycling of spent lithium-ion batteries: From green chemistry to circular economy D Song, J Yu, M Wang, Q Tan, K Liu, J Li Energy Storage Materials, 102870, 2023 | 16 | 2023 |
Pollution-free recycling of lead and sulfur from spent lead-acid batteries via a facile vacuum roasting route M Wang, Q Tan, J Yu, D Xia, W Zhang, CC Zhang, Z Zhang, J Wang, K Liu, ... Green Energy and Resources 1 (1), 100002, 2023 | 9 | 2023 |
Segregation of coal particles in air classifier: Effect of particle size and density H Li, Y He, J Yang, X Zhu, Z Peng, J Yu Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 40 …, 2018 | 6 | 2018 |
Effect of fine particles on the breakage behavior of coarse coal in the hardgrove Mill W Xie, Y He, Y Wang, Y Zhang, J Yu, S Wang, K Li International Journal of Coal Preparation and Utilization 37 (6), 326-338, 2017 | 6 | 2017 |
Comparison of float-sink and progressive release flotation of ground products of coal middlings W Xie, Y He, C Luo, X Zhang, H Li, J Yu, H Wang, F Shi Physicochemical Problems of Mineral Processing 51 (2), 675-684, 2015 | 5 | 2015 |
Batch Production of Lead Sulfate from Spent Lead–Acid Batteries via an Oxygen-Free Roasting Route: A Negative-Carbon Strategy K Liu, M Wang, J Yu, Q Tan ACS Sustainable Chemistry & Engineering 11 (18), 7244-7252, 2023 | 4 | 2023 |
Valorization of waste graphite in spent lithium-ion batteries to graphene via modified mechanical exfoliation and the mechanism exploration Y Liu, J Yu, Y Zhao, J Lai, J Li, Q Tan Journal of Cleaner Production 449, 141823, 2024 | | 2024 |