研究成果

科研项目

国家自然科学基金面上项目“纤维基三明治夹芯结构电子皮肤的可控制备及动态压力传感机制研究”(51873030),主持,2019.1.1-2022.12.31,59万

国家自然科学基金青年基金项目“多级粗糙半封闭孔道纳米纤维膜的可控制备及其摩擦发电机理研究”(51703022),主持,2018.1.1-2020.12.31,26万

上海市青年科技启明星计划项目“纤维基柔性压力传感器的制备及其在随身连续脉搏监测中的应用”,主持,2019.4.1-2022.3.31, 40万

上海市自然科学基金项目“高灵敏度可呼吸电子皮肤的结构设计及其力学响应机制研究” (18ZR1402100),主持,2018.6.1-2021.5.31,20万

东华大学励志计划人才项目“纤维基电子皮肤的结构设计及其压力响应机制研究” (LZB2017002),主持,2018.1-2020.12,50万

纤维材料改性国家重点实验室开放课题“基于纤维的人体机械能收集器件制备及应用” (LK1712),主持,2017.12-2019.12,5万

纺织面料技术教育部重点实验室开放课题“基于纤维的柔性可穿戴纳米发电器件制备及应用”(KLTST201624),主持,2016.1.1-2017.12.31,3万

高性能纤维及制品教育部重点实验室开放课题“碳纤维基高性能摩擦纳米发电机的结构设计及人体机械性能收集”(2232019G-02),主持,2018.11-2020.10,3万

东华大学青年教师启动资助项目“基于静电纺纤维的摩擦纳米发电机制备与性能调控”(101-07-00053056),主持,2016.10-2017.10,5万

上海市科委优秀学术带头人计划项目“陶瓷纳米纤维材料的柔性弹性化设计及其机制研究” (18XD1400200),第二负责人,2018.5.1-2021.4.30,40万

国家重点研发计划项目第三课题“高强抗老化土工材料多重结构复合加工关键技术研究”   (2016YFGX01021003),技术骨干,2016.6-2020.12,467万

上海市教委科研创新计划重大项目“室内VOCs净化用高强度TiO2纳米纤维材料的可控制备及其强韧化机制研究”   (15JC1400500),技术骨干,2018.1.1-2022.12.31,300万


代表论文

近5年已在Energy Environ. Sci.Adv. Mater.Nano EnergyACS Nano等学术刊物上发表SCI收录论文41篇(单篇最高影响因子30.07,影响因子>10的16篇,一区论文22篇,ESI高被引论文6篇),研究成果已被Nature, Nat. Energy, Nat. Commun., Sci. Adv.等期刊引用1500余次(Google Scholar),单篇最高被引250余次,H指数17,出版英文合编书籍1部,申请中国发明专利21项,以第一发明人获授权发明专利8项。

[1].Zhaoling Li#, Jun Chen#, Jin Yang#,   Yuanjie Su, Xing Fan, Ying Wu, Chongwen Yu, Zhong Lin Wang*. β-cyclodextrin   enhanced triboelectrification for self-powered phenol detection and   electrochemical degradation. Energy   & Environmental Science. 2015, 8, 887–896. (IF=30.07)   

[2].Zhaoling Li#, Jun Chen#, Hengyu   Guo,  Xing Fan,  Zhen Wen,  Min-Hsin   Yeh,  Chongwen Yu,  Xia Cao*, Zhong Lin Wang*.   Triboelectrification enabled self-powered detection and removal of heavy metal   ions in wastewater, Advanced   Materials. 2016, 28,   2983-2991. (IF=21.95)

[3].Zhaoling Li#, Jun Chen#, Jiajia Zhou,   Li Zheng, Ken C. Pradel, Xing Fan, Hengyu Guo, Zhen Wen, Min-Hsin Yeh,   Chongwen Yu*, Zhong Lin Wang*. High-efficiency ramie fiber degumming and   self-powered degumming wastewater treatment using triboelectric nanogenerator.   Nano Energy. 2016, 22, 548-557. (IF=13.12)

[4].Zhaoling Li#, Jiali   Shen#, Ibrahim Abdalla, Jianyong Yu, Bin Ding*. Nanofibrous   Membrane Constructed Wearable Triboelectric Nanogenerator for   High Performance Biomechanical Energy Harvesting. Nano Energy. 2017,   36, 341-348. (IF=13.12)

[5].Zhaoling Li#, Miaomiao Zhu#, Qian Qiu#, Jianyong Yu, Bin   Ding*. Multilayered fiber-based triboelectric nanogenerator with high   performance for biomechanical energy harvesting. Nano Energy. 2018, 53,   726-733. (IF=13.12)

[6].Zhaoling Li, Chaoran Meng, Chongwen Yu*. Analysis of oxidized cellulose introduced   into ramie fiber by oxidation degumming. Textile Research Journal.   2015, 85, 2125-2135. (IF=1.54)    

[7].Zhaoling Li, Chaoran   Meng, Jiajia Zhou, Zhengfan Li, Jinhua Ding, Fengming Liu, Chongwen Yu*. Characterization   and control of oxidized cellulose in ramie fibers during oxidative degumming.   Textile Research Journal. 2017, 87, 1828-1840. (IF=1.54)

[8].Zhaoling Li, Chongwen Yu*. The Effect of   Oxidation-reduction Potential on the Degumming of Ramie Fibers with Hydrogen   Peroxide. Journal of the Textile   Institute. 2015, 106,   1251-1261. (IF=1.17)

[9].Zhaoling Li, Chongwen Yu*. Effect of Peroxide and Softness Modification   on Properties of Ramie Fiber. Fibers   and Polymers. 2014,   15, 2105-2111. (IF=1.35)

[10].Jiali Shen#, Zhaoling Li#, Jianyong Yu, Bin Ding*. Humidity-Resisting   Triboelectric Nanogenerator for High Performance Biomechanical Energy   Harvesting. Nano Energy. 2017, 40, 282-288.(co-first   author) (IF=13.12)

[11].Jun Chen#, Jin Yang#,   Zhaoling Li#, Xing Fan, Yunlong Zi, Qingshen Jing,   Hengyu Guo, Zhen Wen, Ken C. Pradel, Simiao Niu, Zhong Lin Wang*. Networks of   Triboelectric Nanogenerators for Harvesting Water Wave Energy: A Potential   Approach toward Blue Energy. ACS   Nano. 2015, 9,   3324–3331. (co-first author) (IF=13.71)

[12].Qian Qiu#, Miaomiao Zhu#, Zhaoling Li*, Kaili Qiu, Xiaoyan Liu, Jianyong Yu, Bin   Ding*.Highly flexible, breathable,   tailorable and washable power generation fabrics for wearable electronics. Nano Energy. 2019, 58, 750-758.   (IF=13.12)

[13].Ibrahim Abdalla, Ahmed Salim,   Miaomiao Zhu, Jianyong Yu, Zhaoling   Li*, Bin Ding*. Light and Flexible Composite Nanofibrous Membranes   for High-Efficiency Electromagnetic Absorption in a Broad Frequency. ACS Applied Materials &   Interfaces. 2018,   10, 44561-44569. (IF=8.097)

[14].Ibrahim Abdalla, Jiali Shen, Jianyong Yu, Zhaoling Li*, Bin Ding*. Co3O4/carbon   composite nanofibrous membrane enabled high-efficiency electromagnetic wave   absorption. Scientific Reports. 2018, 8, 12402. (IF=4.12)

[15].Ibrahim Abdalla, Jianyong Yu, Zhaoling   Li*, Bin Ding*. Nanofibrous Membrane Constructed Magnetic Materials   for High-efficiency Electromagnetic Wave Absorption. Composites Part B: Engineering.   2018, 155, 397-404. (IF=4.92)

[16].Jin Yang#,   Jun Chen#, Yuanjie Su, Qingshen Jing, Zhaoling Li,   Fang Yi, Xiaonan Wen, Zhaona Wang, Zhong Lin Wang*. Eardrum-Inspired Active   Sensors for Self-Powered Cardiovascular System Characterization and   Throat-Attached Anti-Interference Voice Recognition. Advanced Materials. 2015, 27, 1316–1326.(IF=21.95)   

[17].Xing Fan#, Jun Chen#,   Jin Yang, Peng Bai,Zhaoling Li, Zhong Lin Wang*. Ultrathin,   Rollable, Paper-Based Triboelectric Nanogenerator for Acoustic Energy   Harvesting and Self-Powered Sound Recording. ACS Nano. 2015,9, 4236–4243. (IF=13.71)

[18].Zhaona Wang#, Ruomeng Yu#,   Caofeng Pan,Zhaoling Li, Jin Yang, Fang Yi, Zhong Lin Wang*.   Light-induced pyroelectric effect as an effective approach for ultrafast UV   nanosensing. Nature Communications.   2015, 6, 8401. (IF=12.35)

[19].Hengyu Guo#, Jun Chen#,   Min-Hsin Yeh, Xing Fan, Zhen Wen,Zhaoling Li, Long Lin,   Chenguo Hu, Zhong Lin Wang*. An ultra-robust high performance triboelectric   nanogenerator based on charge replenishment. ACS Nano. 2015, 9, 5577-5584. (IF=13.71)

[20].Jie Wang#,  Xiuhan   Li#, Yunlong Zi, Sihong Wang, Zhaoling Li, Li   Zheng, Fang Yi, Shengming Li, Zhong Lin Wang*. A flexible   fiber-based supercapacitor-triboelectric nanogenerator power system for   wearable electronics. Advanced   Materials. 2015, 27,   4830–4836. (IF=21.95)

[21].Zhen Wen#, Jun Chen#,   Min-Hsin Yeh#, Hengyu Guo, Zhaoling Li, Xing Fan,   Tiejun Zhang, Liping Zhu, Zhong Lin Wang*. Blow-Driven Triboelectric   Nanogenerator as an Active Alcohol Breath Analyzer. Nano Energy. 2015, 16, 38–46. (IF=13.12)

[22].Min-Hsin Yeh#, Hengyu Guo#,   Long Lin, Zhen Wen, Zhaoling Li,   Chenguo Hu, Zhong Lin Wang*. Rolling friction enhanced free-standing   triboelectric nanogenerators and its applications in self-powered   electrochemical recovery system. Advanced   Functional Materials. 2016, 26, 1054-1062. (IF=13.33)

[23].Jun Chen#, Jin Yang#, Hengyu Guo, Zhaoling Li, Li Zheng, Zhen Wen, Xing Fan, Zhong Lin Wang*. 

  

专利专著


参编书籍:

[1].Zhaoling Li, Miaomiao   Zhu, Ibrahim Abdalla, Jianyong Yu and Bin Ding. “Morphology and Structure of   Electrospun Nanofibrous Materials” In: Editor Yanbo Liu and Ce Wang,   “Advanced Nanofibrous Materials Manufacture Technology Based on   Electrospinning” United States, Boca Raton, CRC Press- Taylor & Francis   Group, 2018, pp 179-211.

授权中国发明专利:

1. 李召岭, 孟超然, 郁崇文, 李世刚, 黄卫平, 杨建平, 张斌. 一种提高氧化脱胶苎麻精干麻物理机械性能的方法. 中国发明专利授权号: ZL 201310152516.3.

2. 李召岭, 郁崇文, 杨建平, 李世刚, 黄卫平, 张元明. 一种苎麻纤维制备与化学改性同浴进行的方法. 中国发明专利授权号: ZL 201310153380.8.

3. 李召岭, 郁崇文, 赵强, 杨建平, 张斌, 李世刚, 黄卫平. 一种氧化脱胶多次分步投料制备苎麻纤维的方法. 中国发明专利授权号: ZL 201310153378.0.

4. 李召岭, 刘凤明, 孟超然, 郁崇文, 白洋, 臧英明. 一种基于氧化还原电位调控的制备苎麻纤维的方法. 中国发明专利授权号: ZL 201410156559.3 

5. 李召岭, 关赛鹏, 张弘强, 张一帆, 郁崇文. 一种苎麻纳米纤维素疏水化改性的方法. 中国发明专利授权号: ZL 201410217597.5

6. 李召岭, 郭营, 王辉, 郁崇文. 一种改性苎麻纳米纤维素与聚乳酸复合薄膜的制备方法. 中国发明专利授权号: ZL 201410217621.5

7. 李召岭, 孟超然, 李可欣, 郁崇文, 白洋, 臧英明. 一种用苎麻精干麻制备微纤化纳米纤维素的方法. 中国发明专利授权号: ZL 201410157427.2

8. 李召岭, 周佳佳, 孟超然, 郁崇文, 杨建平, 丁金花, 刘凤明. 一种苎麻氧化脱胶过程中氧化纤维素生成的调控方法. 中国发明专利授权号: ZL 201510552462.9


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