个人简历
钱涛,副研究员,苏州大学首批优秀青年学者入选者。2014年6月于南京大学获得博士学位,同年加入苏州大学能源学院。主要从事聚合物材料在新型能量存储与转换体系中的应用研究。在锂-硫电池、锌-空气电池、氮气还原等电化学系统的关键材料合成、原位分析器件设计及构效关系研究方面取得多项创新成果。以第一作者或通讯作者在Nature Communications,Advanced Materials,Nano Letters,Advanced Functional Materials,ACS Nano,Advanced Energy Materials等国际高水平期刊发表学术论文60余篇。近年来主持国家自然科学基金等科研项目4项。长期受邀担任Nature Communications,Advanced Materials, Angewandte Chemie International Edition, Advanced Functional Materials, Advanced Energy Materials, Small等期刊审稿人。
研究领域
""1、光/电化学固氮r2、高比能电池r3、有机二维材料""""
近期论文
Mengfan Wang, Sisi Liu,Tao Qian,* Jie Liu, Jinqiu Zhou, Haoqing Ji, Jie Xiong, Jun Zhong, and Chenglin Yan,* Over 56.55% Faradaic Efficiency of Ambient Ammonia Synthesis Enabled by Positively Shifting the Reaction Potential,Nature Communications, 2019, 10, 341.rrXiaowei Shen, Yutao Li,Tao Qian,* Jie Liu, Jinqiu Zhou, and Chenglin Yan,* John B. Goodenough,* Lithium Anode Stable in Air for Low-Cost Fabrication of a Dendrite-Free Lithium Battery,Nature Communications, 2019, 10, 900.rrSisi Liu, Mengfan Wang, Xinyi Sun, Na Xu, Jie Liu, Yuzhou Wang,Tao Qian,* and Chenglin Yan,*Facilitated Oxygen Chemisorption in Heteroatom-Doped Carbon for Improved Oxygen Reaction Activity in All-Solid-State Zinc–Air Batteries,Advanced Materials, 2018, 30, 1704898.rrJinqiu Zhou,Tao Qian,* Na Xu, Mengfan Wang, Xuyan Ni, Xuejun Liu, Xiaowei Shen, and Chenglin Yan,*Selenium-Doped Cathodes for Lithium–Organosulfur Batteries with Greatly Improved Volumetric Capacity and Coulombic Efficiency, Advanced Materials, 2017, 29, 1701294.rrTingzhou Yang,Tao Qian,* Mengfan Wang, Xiaowei Shen, Na Xu, Zhouzhou Sun, and Chenglin Yan,*A Sustainable Route from Biomass Byproduct Okara to High Content Nitrogen-Doped Carbon Sheets for Efficient Sodium Ion Batteries,Advanced Materials, 2016, 28, 539−545.rrChaoqun Niu, Jie Liu,Tao Qian,* Xiaowei Shen, Jinqiu Zhou, Chenglin Yan,* Single Lithium–ion Channel Polymer Binder for Stabilizing Sulfur Cathodes,National Science Review, In PressrrJinqiu Zhou,Tao Qian,* Jie Liu, Mengfan Wang, Li Zhang, and Chenglin Yan,* High-Safety All-Solid-State Lithium-Metal Battery with High-Ionic-Conductivity Thermoresponsive Solid Polymer Electrolyte,Nano Letters, 2019, 19, 3066-3073.rrTingzhou Yang,Tao Qian,* Yawen Sun, Jun Zhong, Federico Rosei,* Chenglin Yan,*Mega High Utilization of Sodium Metal Anodes Enabled by Single Zinc Atom Sites,Nano Letters, 2019, 19, 7827-7835.rrJie Liu,Tao Qian,*Mengfan Wang, Xuejun Liu, Na Xu,Yizhou You, and Chenglin Yan,*Molecularly Imprinted Polymer Enables High-Efficiency Recognition and Trapping Lithium Polysulfides for Stable Lithium Sulfur Battery, Nano Letters, 2017, 17, 5064–5070.rrNa Xu,Tao Qian,* Xuejun Liu, Jie Liu, Yu Chen, and Chenglin Yan,*Greatly Suppressed Shuttle Effect for Improved Lithium Sulfur Battery Performance through Short Chain Intermediates,Nano Letters, 2017, 17, 538–543.rrTingzhou Yang,Tao Qian,* Jie Liu, Na Xu, Yutao Li,* Nicholas Grundish, Chenglin Yan,* and John B. Goodenough, A New Type of Electrolyte System To Suppress Polysulfide Dissolution for Lithium−Sulfur Battery,ACS Nano, 2019, 13, 9067−9073.rrXuyan Ni,Tao Qian,* Xuejun Liu, Na Xu, Jie Liu, and Chenglin Yan,* High Lithium Ion Conductivity LiF/GO Solid Electrolyte Interphase Inhibiting the Shuttle of Lithium Polysulfides for Long-Life Li–S Battery,Advanced Functional Materials, 2018, 28, 1706513.rrXuejun Liu, Na Xu,Tao Qian,* Jie Liu, Xiaowei Shen, and Chenglin Yan,*High Coulombic Efficiency and High-Rate Capability Lithium Sulfur Batteries with Low-Solubility Lithium Polysulfides by Using Alkylene Radicals to Covalently Connect Sulfur,Nano Energy, 2017, 41, 758–764.rrXiaowei Shen, Haoqing Ji, Jie Liu, Jinqiu Zhou, Chenglin Yan, andTao Qian,* Super Lithiophilic SEI Derived from Quinones Electrolyte to Guide Li Uniform Deposition,Energy Storage Materials, 2019, In press.rrXuejun Liu, Na Xu,Tao Qian,* Jie Liu, Xiaowei Shen, and Chenglin Yan,*High Coulombic Efficiency and High-Rate Capability Lithium Sulfur Batteries with Low-Solubility Lithium Polysulfides by Using Alkylene Radicals to Covalently Connect Sulfur,Nano Energy, 2017, 41, 758–764.
