代表论著 [1] Bin Sun, KangKang Bao, Panpan Wang, Kai Liu, Hui Wu*, and Yang Jin*Toward Stimulating the Chemistry Process for Garnet Electrolyte-Based Molten Li-S Batteries: Modulation of the End-Product in the Cathode with High Loading, ACS Nano, 2024. (IF.17.1) [2] Kangkang Bao, Minghui Wang, Yue Zheng, Panpan Wang, Liwen Yang, Yang Jin, Hui Wu, Bin Sun*,Construction of low dielectric aqueous electrolyte with ethanol for highly stable Zn anode,Nano Energy 120 (2024) 109089. (IF.17.6) [3] Panpan Wang, Bin Sun*, Kangkang Bao, Hengyu Yang, Yongle Liang, Minghui Wang, Xiaolin Wei, Liwen Yang, Nitrate Radical Induced “Two in One” Interface Engineering toward High Reversibility of Zn Metal Anode, Small, 2023, 2304896- 2304905. (IF.15.1) [4] Bin Sun, Yuanzhi Zong, Kangkang Bao, Minghui Wang, Panpan Wang, Huaxing Xu, Yang Jin. Activating Gel Polymer Electrolyte Based Zinc-Ion Conduction with Filler-Integration for Advanced Zinc Batteries, ACS Appl. Mater. Interfaces 2023, 15, 31. [5] Sun Bin, Kangkang Bao, Panpan Wang, Yuanzhi Zong, Zili Zhang, Jing Xu, Qianzheng Jin, Huaxing Xu, Yang Jin. Integration of Three Functional Layers Constructed Simultaneously in Combustion Process for Reversible Zinc Anode[J]. Applied Surface Science, 2023: 156384. [6] Wang Panpan, Sun Bin*, Wei Xiaolin, Yang Liwen, Wu Hui. Stimulating Zn2+ Permselectivity for Prominent Zinc Anode Reversibility by Designing a Self-Assembled Artificial Layer. Chemical Engineering Journal, 2022: 140827. [7] Bin Sun, Panpan Wang, Liwen Yang, Xiaolin Wei, Yang Jin, and Hui Wu. Rational Design of an Interfacial Bilayer for Aqueous Dendrite-Free Zinc Anodes. ACS Appl. Mater. Interfaces 2022, 14, 954−960. (影响因子>10) [8] Bin Sun, Panpan Wang, Jing Xu, Qianzheng Jin, Zili Zhang, Hui Wu, and Yang Jin. A garnet-electrolyte based molten Li-I2 battery with high performance. Nano Res. 2022, 15, 4076–4082. (影响因子>10) [9] Qianzheng Jin, Hongfei Lu, Zili Zhang, Jing Xu, Bin Sun,* Yang Jin,* and Kai Jiang*. Synergistic Manipulation ofNa+ Flux and Surface-Preferred Effect Enabling High-Areal-Capacity and Dendrite-Free Sodium Metal Battery. Adv. Sci. 2022, 2103845. (影响因子>10) [10] Kai Liu, Jialiang Lang, Minzheng Yang, Jing Xu, Bin Sun, Yulong Wu, Kuangyu Wang, Zhikun Zheng, Zeya Huang, Chang-an Wang, Hui Wu, Yang Jin, and Yi Cui. Molten Lithium-Brass/Zinc Chloride System as High-Performance and Low-Cost Battery. Matter. 2020, 3, 1714–1724. (影响因子>10) [11] Bin Sun, Zili Zhang , Jing Xu, Yanpeng Lv, Yang Jin. Composite separator based on PI film for advanced lithium metal batteries. Journal of Materials Science & Technology, 2022, 102, 264–271. (影响因子>10) [12] Sun, B., Liu, K., Lang, J., Fang, M., Jin, Y., & Wu, H. Ionic liquid enabling stable interface in solid state lithium sulfur batteries working at room temperature. Electrochimica Acta, 2018, 284, 662-668. [13] Sun, B., Fang, M., Huang, Z., & Wu, H. Robust current collector promoting the Li metal anode cycling with appropriate interspaces. Journal of the Electrochemical Society, 2018, 165(10), A2026-A2031. [14] Sun, B., Lang, J., Liu, K., Fang, M., Jin, Y., & Wu, H. Promoting a highly stable lithium metal anode by superficial alloying with an ultrathin indium sheet. Chemical Communication, 2019, 55,1592-1595, [15] Min, X., Sun, B#., Chen, S., Fang, M., Wu, X., Abdelkader, A., & Kumar, R. V. A textile-based SnO2 ultra-flexible electrode for lithium-ion batteries. Energy Storage Materials. 2019, 16, 597-606. (影响因子>10) [16] Sun, B., Lang, J., Liu, K., Fang, M., Jin, Y., & Wu, H. A paint layer for an all solid-state lithium metal battery. Chemical Communications, 2019. 55(47), 6704-6707. [17] Sun, B, Huang K, Qi X, et al. Rational Construction of a Functionalized V2O5 Nanosphere/MWCNT Layer-by-Layer Nanoarchitecture as Cathode for Enhanced Performance of Lithium-Ion Batteries. Advanced Functional Materials, 2015, 25(35): 5633-5639. (影响因子>10) |
