李新宇博士

作者:    时间:2021-03-25    点击数:


一、 基本情况

李新宇,男,1981年生,博士,研究员(校聘教授),硕士生导师,研究方向:新型纳米能源物理与器件(锂硫电池,锌离子电池,超级电容器)。2018年入选广西高等学校千名中青年骨干教师培育计划中国教育发展战略学会人才发展专业委员会专家评审库成员,入选首批屏风学者。国家自然科学基金委项目评审专家,广西、河北等省级自然科学基金项目评审专家。近年来,先后主持国家自然科学基金3项,广西自然科学基金2项。出版专著1部,授权专利1项,在 “Appl. Phys. Lett.”“Carbon” “Journal of Power Sources”, “Journal of Colloid and Interface Science”“Appl. Sur. Sci.”“Electrochim. Acta”  “J. Appl. Phys”等国内外SCI学术期刊上发表学术论文40余篇。

联系地址:广西,桂林市,桂林理工大学理学院 邮编:541004

电子邮址:lixinyu5260@163.com

二、 个人主要经历

20002004 湖南科技大学,电子信息工程专业,获工学学士学位

20042007 湘潭大学,微电子学与固体电子学,获工学硕士学位

20072010 中山大学,凝聚态物理专业,获理学博士

2010~至今 桂林理工大学理学院

三、 主持的研究项目

1). 柔性三维多孔碳结构原位负载赝电容材料的构筑及界面调控增容机制研究,国家自然科学基金(12164013, 2022.01-2025.1238万元,主持

2).量子点嵌入氧化石墨烯薄膜的构建及功能化改性研究,国家自然科学基金(51662004, 2017.01-2020.1239万,主持

3).氧空位调控磁性元素掺杂二氧化钛铁磁性的可逆转变性质研究,国家自然科学基金(11304051, 2014.01-2016.1229万,,主持

4). 主持广西自然科学基金青年、面上项目各一项

四、研究兴趣及指导学生情况

研究兴趣:新型储能材料与器件(金属离子电池)

指导已毕业硕士生名单及去向:

许永杰(2015级,南京大学凝聚态物理专业博士)

徐丹丹(2017级,西安电子科技大学 材料科学与工程专业博士)

宣从旭(2018级,宁波维科新能源科技有限公司

王准(2018级,交通银行安庆分行

李嘉劲(2019级,南京工业大学 化学专业博士)

蒋蕴龙(2019级,福州大学 材料专业博士)

五、专著、教材和专利

1).李新宇,《氧化石墨烯基超级电容器电极材料结构调控与性能研究》,延边大学出版社, 2018.09. ISBN978-7-5688-5859-5

2).李明,肖剑荣,王志勇,李新宇,《光电子技术》,上海交通大学出版社,上海,2017.08ISBN978-7-313-18151-0

3). 李新宇,许永杰,冯玉昆,李明,一种石墨烯量子点诱导高氮掺杂光还原氧化石墨烯制备方法,中国,专利号:201710329827.0

4). 李新宇,肖剑荣,唐涛, 李明, 文剑锋,一种简易制备N型石墨烯场效应管的方法,中国,专利号:201410561468.8

5). 李新宇; 肖剑荣; 文剑锋; 王恒,金属/Mn:TiO2/Nb:SrTiO3/金属异质结的制备及电场调控磁性的方法,中国,专利号:201410361219.4

6).李新宇, 罗涨宾,徐丹丹,许永杰,文剑锋; 一种光照氮掺杂三维石墨烯包覆螺旋碳管复合材料的方法,2020-01-21, 中国,授权专利号:ZL201810476577.8.

4 近期发表的科研论文(第一或通讯作者)

(1)Bin Wang , Xinyu Li * , Yong Cheng **, Yaping Zeng , Ling Liu , Yong Chen , Ming Li , Jianrong Xiao *, Boosting lithium–sulfur battery performance using a phosphating nano-sulfur anchored on graphene framework anode, Journal of Power Sources, 553 (2023) 232269 IF9.796

(2)Meng Xiang, Jiajin Li, Shuaiqiang Feng, Haiyang Zhang, Xueli Cao, Yaping Zeng, Xinyu Li*, Jianrong Xiao*, Synergistic capture and conversion of polysulfides in cathode composites with multidimensional framework structures, Journal of Colloid and Interface Science, 2022, 624:471-481. IF9.965

(3)Jiajin Li, Xinyu Li*, Xin Fan, Tao Tang*, Ming Li, Yaping Zeng, Heng Wang, Jianfen Wen, Jianrong Xiao*, Holey graphene anchoring of the monodispersed nano-sulfur with covalently-grafted polyaniline for lithium sulfur batteries, Carbon, 188 (2022) 155-165.(封面论文)IF11.307

(4)Yunlong Jiang, Xinyu Li*, Fangyuan Liu , Bing Wang , Wenquan Zhou , Shanxu Dong , Xin Fan *, In situ growth and anchoring NiCo2O4 nanowires on self-supported 3D holey graphene framework for supercapacitor, Applied Surface Science, 576 (2022) 151801. IF7.392

(5) Congxu Xuan, Xinyu Li*, Zhun Wang, Hao Wu, Tao Tang, Jianfeng Wen, Ming Li*, and Jianrong Xiao*, Highly efficient polyaniline trapping and covalent grafting within a three-dimensional porous graphene oxide/helical carbon nanotube skeleton for high-performance flexible supercapacitors, ACS Appl. Energy Mater. 2021, 4:523-534.

(6) Zhun Wang, Xinyu Li*, Congxu Xuan, Jiajin Li, Yunlong Jiang, Jianrong Xiao*, Photo-synergetic nitrogendoped MXene/reduced graphene oxide sandwichlike architecture for high-performance lithiumsulfur batteries. Int. J. Energy Res. 2021, 45:2728-2738.

(7) Dandan Xu#, Congxu Xuan#, Xinyu Li*, Zhangbin Luo, Zhun Wang, Tao Tang*, Jianfeng Wen, Ming Li, Jianrong Xiao*, Novel helical carbon nanotubes-embedded reduced graphene oxide in three-dimensional architecture for high-performance flexible supercapacitors, Electrochimica Acta, 2020, 339:135912.

(8) Zhangbin Luo#, Zengren Tao#, Xinyu Li*, Dandan Xu, Congxu Xuan, Zhun Wang, Tao Tang, Jianfeng Wen*, Ming Li and Jianrong Xiao*, Ferroconcrete-Like helical carbon nanotube/reduced graphene oxide heterostructure 3D networks as sulfur hosts for high-performance Li-S batteries, Front. Energy Res., 2020, 7: 157.

(9) Xinyu Li, Yongjie Xu, Guanghui Hu, Zhangbin Luo, Dandan Xu, Tao Tang, Jianfeng Wen*, Ming Li*, Taoyun Zhou*, Yun Cheng, Self-assembled formation of conjugated 3D reduced graphene oxide-wrapped helical CNTs nanostructure and nitrogen-doped using photochemical doping for high-performance supercapacitor electrodes, Electrochimica Acta, 2018, 280: 33-40.

(10)Yi Luo, Ming Li*, Guanghui Hu, Tao Tang, Jianfeng Wen, Xinyu Li*, Liang Wang*, Enhanced photocatalytic activity of sulfur-doped graphene quantum dots decorated with TiO2 nanocomposites, Mater. Res. Bull., 2018, 97: 428-435.

(11) Yongjie Xu, Xinyu Li*, Guanghui Hu, Ting Wu, Yi Luo, Lang Sun, Tao Tang, Jianfeng Wen, Heng Wang, Ming Li*, Graphene oxide quantum dot-derived nitrogen-enriched hybrid graphene nanosheets by simple photochemical doping for high-performance supercapacitors. Applied Surface Science, 2017, 422: 847-855.

(12) Lang Sun, Yi Luo, Ming Li*, Guanghui Hu, Yongjie Xu, Tao Tang, Jianfeng Wen, Xinyu Li*, Liang Wang*, Role of pyridinic-N for nitrogen-doped graphene quantum dots in oxygen reaction reduction, Journal of Colloid and Interface Science, 2017,508:154-158.

(13)  Yi Luo#, Yongjie Xu#, Ming Li*, Lang Sun, Guanghui Hu, Tao Tang, Jianfeng Wen, Xinyu Li*, Tuning the photoluminescence of graphene quantum dots by fluorination, Journal of Nanomaterials, 2017, 2017: 9682846.

(14) Yongjie Xu#, Yukun Feng#, Xinyu Li*, Guanghui Hu, Yi Luo, Lang Sun, Tao Tang, Jianfeng Wen, Heng Wang, and Ming Li, Direct formation of reduced graphene oxide and graphene quantum dot composites by using ascorbic acid as high-performance binder-free supercapacitor electrodes, Inter. J. of Electrochem. Sci., 2017, 12:8820- 8831.

(15) Xinyu LiTao TangMing LiXiangcong HeNitrogen-doped graphene films from simple photochemical doping for n-type field-effect transistorsApplied Physics Letters20151061):013110-1-013110-5.

(16) Xinyu LiTao TangMing LiXiangcong HePhotochemical doping of graphene oxide thin films with nitrogen for electrical conductivity improvementJournal of Materials Science: Materials in Electronics2015263):1770-1775

17). X. Y. Li,* J. R. Xiao, Z. Y. Wang, S. W. LiStructural and magnetic properties of Mn:TiO2 films grown by plasma-assisted molecular beam epitaxy. Mater. Sci. Eng. B , 177, 869, 2012.

18). S. X. Wu, X. Y. Li, X. J. Xing, P. Hu, Y. P. Yu, , and S. W. Li*, Resistive dependence of magnetic properties in nonvolatile Ti/Mn:TiO2/SrTi0.993Nb0.007O3/Ti memory device. Appl. Phys. Lett. 94, 253504, 2009.

19). X. Y. Li*, Mechanisms of 1D Crystal Growth in Chemical Vapor Deposition:ZnO Nanowires. Adv. Mater. Research , 463, 1463, 2012.

20). P. Hu, X.Y. Li, J.Q. Lu, M. Yang, Q.B. Lv, S.W. Li*, Oxygen deficiency effect on resistive   switching characteristics of copper oxide thin films, Phy. Lett. A, 375, 1898, 2011.

21). Y. J. Liu, L. M. Xu, X.Y. Li, P. Hu, and S. W. Li*Growth and magnetic property of ζ-phase Mn2N1±x thin films by plasma-assisted molecular beam epitaxy, J. Appl. Phys., 107, 103914, 2010.

22). X. Y. Li, S. X. Wu, P. Hu, X. J. Xing, Y. J. Liu,Y. P. Yu, M. Yang, J. Q. Lu, S. W. Li* and W. Liu, Structures and magnetic properties of p-type Mn:TiO2 dilute magnetic semiconductor thin films, J. Appl. Phys., 106, 043913, 2009.

23). X. Y. Li, S. X. Wu, L. M. Xu, Y. J. Liu, X. J. Xing, and S. W. Li*, Room-temperature ferromagnetism in (Mn, N)-codoped TiO2 films grown by plasma assisted molecular beam epitaxy. J. Appl. Phys., 104, 093914, 2008.

24). X. Y. Li, S. X. Wu, L. M. Xu, C. T. Li, Y. J. Liu, X. J. Xing, and S. W. Li*, Effects of depositing rate on structure and magnetic properties of Mn:TiO2 films grown by plasma-assisted molecular beam epitaxy. Mater. Sci. Eng. B , 156,  90, 2009.

25). X. Y. Li, J. Guo, S. L. Ding, T. j. Lin, J. T. Dong, Low Temperature Synthesis of Novel ZnO Nanowire Microspheres on Silicon Substrates, Rare Metals, 26, 242, 2007.


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