陳人傑,男,博士,北京理工大學教授,博士生導師。
現擔任中國材料研究學會理事、中國矽酸鹽學會固態離子學分會理事、國際電化學能源科學學會(IAOEES)理事、北京電動車輛協同創新中心(國家級)研究員。
作為負責人,承擔了國家自然科學基金項目、科技部重點研發計畫項目、科技部863計畫項目、科技部國際科技合作項目、中央在京高校重大成果轉化項目、北京市重大科技項目等課題。在Chemical Society Reviews、Advanced Materials、Nature Communications、Advanced Energy Materials、Advanced Functional Materials、Advanced Science、ACS Nano、Nano Letters、Nano Energy、Materials Horizons等期刊發表論文200餘篇,申請發明專利52項,獲授權22項。作為主要完成人,獲得2013年度國家技術發明二等獎、部級科學技術一等獎3項。
基本介紹
- 中文名:陳人傑
- 國籍:中國
- 民族:漢族
- 職業:教授,博士生導師
- 畢業院校:北京理工大學
人物經歷,研究方向,部分成果,
人物經歷
2002年師從北京理工大學吳鋒教授,於2005獲工學博士學位;2005-2007年,在清華大學化學系物理化學專業師從陳立泉院士、邱新平教授從事博士後研究工作;2007年入職北京理工大學;2012-2013年,在英國劍橋大學材料科學與冶金系Prof. Derek Fray、Dr. Vasant R. Kumar課題組訪問研究;現為北京理工大學材料學院教授、博導。
研究方向
陳人傑教授主要從事綠色能源材料、二次電池新體系及關鍵材料等領域的教學和科研工作,開展了多電子高比能二次電池新體系及關鍵材料、新型離子液體及功能電解質材料、特種功能二次電池器件及薄膜材料等方向的系統研究。
部分成果
[1]Zhao Yuanyuan, Ye Yusheng, Wu Feng, Li Yuejiao, Li Li,Chen Renjie*, Anode interface engineering and architecture design for high-performance lithium-sulfur batteries.Advanced Materials, 2019, 1806532.
[2]Huang Yongxin, Zhao Luzi, Li Li, Xie Man,Chen Renjie*, Electrolytes and electrolyte/electrode interfaces in sodium-ion batteries: from scientific research to practical application.Advanced Materials, 2019, 1808393.
[3]Qian Ji, Li Yu, Zhang Menglu, Luo Rui, Wang Fujie, Ye Yusheng, Xing Yi, Li Wanlong, Qu Wenjie, Wang Lili, Li Li, Li Yuejiao, Wu Feng, Chen Renjie*, Protecting lithium/sodium metal anode with metal-organic framework based compact and robust shield. Nano Energy, 2019, 60, 866-874.
[4]Huang Yongxin, Xie Man, Wang Ziheng, Jiang Ying, Huang Qianming, Bai Xuedong, Li Li, Wu Feng, Chen Renjie*, All-iron sodium-ion full-cells assembled via stable porous goethite nanorods with low strain and fast kinetics. Nano Energy, 2019, 60, 294-304.
[5]Zhang Xiaoxiao,Li Li, Fan Ersha, Xue Qing, Bian Yifan, Wu Feng,Chen Renjie*, Toward sustainable and systematic recycling of spent rechargeable batteries.Chemical Society Reviews,2018, 47, 7239-7302.
[6]Qian Ji, Wu Feng, Ye Yusheng, Zhang Menglu, Huang Yongxin, Xing Yi, Qu Wei, Li Li, Chen Renjie*, Boosting fast sodium storage of a large-scalable carbon anode with an ultralong cycle life.Advanced Energy Materials, 2018, 8, 1703159.
[7]Huang Yongxin, Wang Ziheng, Jiang Ying, Li Shuaijie, Wang Min, Ye Yusheng, Wu Feng, Xie Man, Li Li, Chen Renjie*, Conductivity and pseudocapacitance optimization of bimetallic antimony-indium sulfide anodes for sodium-ion batteries with favorable kinetics. Advanced Science, 2018, 5, 1800613.
[8]Huang Yongxin, Wang Ziheng, Jiang Ying, Li Shuaijie, Li Zehua, Zhang Haiqin, Wu Feng, Xie Man, Li Li, Chen Renjie*, Hierarchical porous Co0.85Se@reduced graphene oxide ultrathin nanosheets with vacancy-enhanced kinetics as superior anodes for sodium-ion batteries. Nano Energy, 2018, 53, 524-535.
[9]Ye Yusheng, Wu Feng, Liu Yuting, Zhao Teng, Qian Ji, Xing Yi, Li Wanlong, Huang Jiaqi, Li Li, Huang Qianming, Bai Xuedong,Chen Renjie*, Toward practical high-energy batteries: a modular-assembled oval-like carbon microstructure for thick sulfur electrodes.Advanced Materials,2017, 29, 1700598.
[10]Wu Feng, Xing Yi, Lai Jingning, Zhang Xiaoxiao, Ye Yusheng, Qian Ji, Li Li,Chen Renjie*, Micrometer-sized RuO2catalysts contributing to formation of amorphous Na-deficient sodium peroxide in Na–O2batteries.Advanced Functional Materials,2017, 27, 1700632.
[11]Wu Feng, Ye Yusheng, Huang Jiaqi, Zhao Teng, Qian Ji, Zhao Yuanyuan, Li Li, Wei Lei, Luo Rui, Huang Yongxin, Xing Yi,Chen Renjie*, Sulfur nanodots stitched in 2D “bubble-like” interconnected carbon fabric as reversibility-enhanced cathodes for lithium−sulfur batteries.ACS Nano,2017, 11, 4694-4702.
[12]Wu Feng, Chen Nan, Chen Renjie*, Wang Lili, Li Li, Organically modified silica-supported ionogels electrolyte for high temperature lithium-ion batteries, Nano Energy, 2017, 31, 9-18.
[13]Huang Yongxin, Xie Man, Zhang Jiatao, Wang Ziheng, Jiang Ying, Xiao Genhua, Liang Shuaijie, Li Li, Wu Feng, Chen Renjie*, A novel border-rich Prussian blue synthetized by inhibitor control as cathode for sodium ion batteries. Nano Energy, 2017, 39, 273-283.
[14]Tan Guoqiang, Wu Feng*, Yuan Yifei,Chen Renjie*, Zhao Teng, Yao Ying, Qian Ji, Liu Jianrui, Ye Yusheng, Shahbazian-Yassar Reza, Lu Jun*,Amine Khalil, Freestanding three-dimensional core-shell nanoarrays for lithium-ion battery anodes.Nature Communications, 2016, 7:11774.
[15]Wu Feng, Chen Nan,Chen Renjie*, Zhu Qizhen, Tan Guoqiang, Li Li.Self-regulative nanogelator solid electrolyte: a new option to improve the safety of lithium battery.Advanced Science,2016, 3(1), 1500306.
[16]Chen Renjie*, Luo Rui, Huang Yongxin, Wu Feng*, Li Li. Advanced high energy density secondary batteries with multi-electron reaction materials.Advanced Science,2016, 3, 1600051.
[17]Chen Renjie*, Qu Wenjie, Guo Xing, Li Li, Wu Feng, The pursuit of solid-state electrolytes for lithium batteries: from comprehensive insight to emerging horizons. Materials Horizons, 2016, 3, 487-516.
[18]Wu Feng, Ye Yusheng, Chen Renjie*, Qian Ji, Zhao Teng, Li Li, Li Wenhui, Systematic effect for an ultra long cycle lithium-sulfur battery. Nano Letters,2015,15(11), 7431-7439.
[19]Wu Feng, Zhu Qizhen, Chen Renjie*, Chen Nan, Chen Yan, Li Li, Ionic liquid electrolytes with protective lithium difluoro(oxalate)borate for high voltage lithium-ion batteries. Nano Energy. 2015, 13, 546-553.
[20]Chen Renjie*, Zhao Teng, Wu Weiping, Wu Feng*, Li Li, Qian Ji, Xu Rui, Wu Huiming, Albishri Hassan M., Al-Bogami A. S., El-Hady Deia Abd, Lu Jun*, Amine Khalil*, Free-standing hierarchically sandwich-type tungsten disulfide nanotubes/graphene anode for lithium-ion batteries. Nano Letters. 2014, 14 (10), 5899–5904.
[21]Chen Renjie, Zhao Teng, Lu Jun, Wu Feng*, Li Li*, Chen Junzheng, Tan Guoqiang, Ye Yusheng, Amine Khalil*. Graphene-based three-dimensional hierarchical sandwich-type architecture for high-performance Li/S batteries, Nano Letters, 2013, 13(10), 4642-4649.
[22]Wu Feng, Tan Guoqiang, Chen Renjie*, Li Li*, Xiang Jin, Zheng Yuelei. Novel solid-state Li/LiFePO4 battery configuration with a ternary nanocomposite electrolyte for practical applications. Advanced Materials, 2011, 23, 5081-5085.
