| Layered double hydroxide membrane with high hydroxide conductivity and ion selectivity for energy storage device J Hu, X Tang, Q Dai, Z Liu, H Zhang, A Zheng, Z Yuan, X Li Nature Communications 12 (1), 3409, 2021 | 192 | 2021 |
| Thin-film composite membrane breaking the trade-off between conductivity and selectivity for a flow battery Q Dai, Z Liu, L Huang, C Wang, Y Zhao, Q Fu, A Zheng, H Zhang, X Li Nature communications 11 (1), 13, 2020 | 192 | 2020 |
| Low-cost hydrocarbon membrane enables commercial-scale flow batteries for long-duration energy storage Z Yuan, L Liang, Q Dai, T Li, Q Song, H Zhang, G Hou, X Li Joule 6 (4), 884-905, 2022 | 109 | 2022 |
| Membranes with well‐defined selective layer regulated by controlled solvent diffusion for high power density flow battery M Shi, Q Dai, F Li, T Li, G Hou, H Zhang, X Li Advanced Energy Materials 10 (34), 2001382, 2020 | 68 | 2020 |
| High-performance PBI membranes for flow batteries: from the transport mechanism to the pilot plant Q Dai, F Xing, X Liu, D Shi, C Deng, Z Zhao, X Li Energy & Environmental Science 15 (4), 1594-1600, 2022 | 66 | 2022 |
| A defect-free MOF composite membrane prepared via in-situ binder-controlled restrained second-growth method for energy storage device J Wu, Q Dai, H Zhang, X Li Energy Storage Materials 35, 687-694, 2021 | 55 | 2021 |
| Highly stable aromatic poly (ether sulfone) composite ion exchange membrane for vanadium flow battery Z Yuan, Q Dai, L Qiao, Y Zhao, H Zhang, X Li Journal of Membrane Science 541, 465-473, 2017 | 55 | 2017 |
| Advanced porous membranes with tunable morphology regulated by ionic strength of nonsolvent for flow battery L Qiao, H Zhang, W Lu, Q Dai, X Li ACS applied materials & interfaces 11 (27), 24107-24113, 2019 | 53 | 2019 |
| Polypyrrole modified porous poly (ether sulfone) membranes with high performance for vanadium flow batteries Z Yuan, Q Dai, Y Zhao, W Lu, X Li, H Zhang Journal of Materials Chemistry A 4 (33), 12955-12962, 2016 | 53 | 2016 |
| Ion conductive membranes for flow batteries: design and ions transport mechanism Q Dai, Z Zhao, M Shi, C Deng, H Zhang, X Li Journal of Membrane Science 632, 119355, 2021 | 40 | 2021 |
| Recent development in composite membranes for flow batteries J Wu, Q Dai, H Zhang, X Li ChemSusChem 13 (15), 3805-3819, 2020 | 36 | 2020 |
| Advanced scalable zeolite “ions-sieving” composite membranes with high selectivity Q Dai, W Lu, Y Zhao, H Zhang, X Zhu, X Li Journal of Membrane Science 595, 117569, 2020 | 35 | 2020 |
| Proton and molecular permeation through the basal plane of monolayer graphene oxide ZF Wu, PZ Sun, OJ Wahab, YT Tan, D Barry, D Periyanagounder, ... Nature Communications 14 (1), 7756, 2023 | 24 | 2023 |
| Porous membrane with high selectivity for alkaline quinone-based flow batteries D Chen, W Duan, Y He, T Li, C Kang, Q Dai, Z Yuan, X Li ACS Applied Materials & Interfaces 12 (43), 48533-48541, 2020 | 23 | 2020 |
| Solvent treatment: the formation mechanism of advanced porous membranes for flow batteries W Lu, L Qiao, Q Dai, H Zhang, X Li Journal of Materials Chemistry A 6 (32), 15569-15576, 2018 | 18 | 2018 |
| A highly stable membrane for vanadium flow batteries (VFBs) enabled by the selective degradation of ionic side chains Z Zhao, Q Dai, X Li, S Zhang, S Li, X Li Journal of Materials Chemistry A 10 (2), 762-771, 2022 | 15 | 2022 |
| Highly stable side-chain-type cardo poly (aryl ether ketone) s membranes for vanadium flow battery Z Zhao, Q Dai, S Huang, W Lu, Y Chen, J Zheng, S Zhang, S Li, X Li Chinese Chemical Letters 35 (3), 109231, 2024 | 5 | 2024 |
| Macro-scale Turing-shape membranes for energy storage L Qiao, Q Dai, H Zhang, X Li Cell Reports Physical Science 2 (3), 2021 | 4 | 2021 |