丁旭丽
时间:2024-04-08 16:29 来源: 作者: 点击:次
丁旭丽 副教授 理学院 个人邮箱: xuliding@just.edu.cn 办公地点: 通讯地址: 江苏省镇江市丹徒区长晖路666号 邮政编码: 212100 传真: 您是第6901 位访问者 个人简介 丁旭丽, 女,汉族,山东潍坊人,理学博士,副教授,硕士研究生导师。主要承担《固体物理》、《半导体物理与器件》、《材料科学与基础》、《光电子学》等课程教学工作,开展新型储能材料设计与构筑、锂离子电池、钠离子电池、物理化学界面调控等方向的科研工作。近年来在Nano Energy (IF=19.069), Journal of Material Chemcitry A (IF=14.511), Carbon (IF=11.307), ACS Applied Materials & Interfaces (IF=10.383), Journal of Material Chemistry C (IF=8.067), Electrochemica Acta (IF=7.335), ACS Applied Energy Materials (IF=6.959), Advanced Materials Interfaces (IF=6.389), Physical Review B (IF=3.908,Nature index)等期刊发表论文40余篇,主持及参与国家自然科学基金面上项目、青年项目、重点项目等科研项目10余项,国家发明专利12项, 授权6项。先后入选江苏省高校 “青蓝工程”中青年学术带头人,江苏省“六大人才高峰”-高层次人才,江苏省科技副总,镇江市科技创新团队,江苏科技大学优秀教师等。 研究方向 (1)新型高比能储能材料设计与构筑; (2)锂离子、钠离子动力与储能电池; (3)物理化学界面调控; (4)下一代电池关键材料与技术。 教育经历 2018/11-至今,江苏科技大学,理学院,副教授,硕士研究生导师2022/09-2023.02, 厦门大学,化学化工学院,物理化学,访问学者2014/01-2018/11,同济大学,高等研究院,新能源材料与器件,副研究员2012/09-2014/01,韩国首尔国立大学,物理与天文学院,凝聚态物理,博士后2009/09-2012/09,上海交通大学,物理与天文学院,凝聚态物理,博士 课程教学 本科生:固体物理半导体物理材料科学与基础研究生及留学生:新能源材料与器件光电子学 科研项目 [1] 国家自然科学基金面上项目, 在研, 主持;[2] 国家自然科学基金青年项目, 结题, 主持;[3] 国家自然科学基金国际合作与交流项目, 结题,主持;[4] 江苏省高校“青蓝工程”中青年学术带头人培育项目,在研,主持;[5] 江苏省第十六批“六大人才高峰”高层次人才, XNY-074, 在研,主持;[6] 国家自然科学基金重点项目(51632001,在研)2017.01~2021.12,结题,参与;[7] 江苏省高层次人才产学研项目,结题,主持;[8] 江苏科技大学高水平科技成果奖培育项目(在研),2021-2025,主持;[9] 中科院能量转换与存储重点实验室项目(CK1300804)结题,主持;[10] 江苏科技大学人才引进项目, 1052931707,在研, 主持;[11] 产学研合作项目, 2017~2019, 参与。 专利成果 [1] 丁旭丽; 黄云辉; 贺鹏飞; 吴广明, 一种用于锂离子电极的硅基材料及其制备方法,专利号:ZL. 201610908385.0, 2016(授权)[2] 丁旭丽;赵洪达;梁道伟,一种用于锂离子电池的氧化硅基负极材料及其制备方法,专利号:ZL. 2020 1 0842620.5(授权)[3]丁旭丽;赵洪达;梁道伟,一种氧化硅-碳丝活性材料及其制备方法和应用,专利号:ZL. 202011403814.1, 2021(授权)[4] 丁旭丽,张宁,赵洪达,谌潇靖,氧化硅/磷化物碳化复合物及其制备方法和应用,专利号:ZL. 202110836100.8, 2022(授权)[5] 丁旭丽;黄云辉,一种锂离子电池负极材料SiO@Al@C的制备方法及应用,专利号:ZL 201810233588.3(授权)[6] 丁旭丽; 梁道伟,一种基于硅藻土基的锂离子电池负极材料及其制备方法, 专利号:ZL 201911232460.6(授权)[7] 丁旭丽,谌潇靖,赵洪达,张宁,磷基复合材料及制法、钠离子二次电池负极及二次电池,专利号:202111010223.2, 2021 (公开)[8] 谌潇靖,丁旭丽,张宁,一种锡锑氧化物复合材料及其制备方法与其在制备电池负极上的应用,专利号:2022101813780,2022.[9] 马鑫荣,谌潇靖,申欣,葛庆磊,范丽桢,朱添宇,丁旭丽, 一种钠离子负极材料及制备方法与钠离子电池, 专利号:202111573116.0, 2021.[10] 张宁,丁旭丽,谌潇靖,一种同芯异质离子负极材料的制备及二次电池, 2022.[11] 赵娇娇,李强,丁旭丽,一种半固态氧化硅电极材料的制备及二次电池, 2023.[12] 李强,赵娇娇,丁旭丽,一种金属复合的二氧化硅负极材料的制备及应用, 2023. 科研团队 1 科研团队 2 组内动态: 获奖动态 2022.06.15 祝贺赵洪达同学获优秀毕业生 论文著作 [1] Qiang Li, Jiaojiao Zhao, Wang Yao, Chuejie Yu, Xuli Ding*, A SiO2@Al as Stable and Long-cycle Anode for Lithium-ion Batteries, Materials Chemistry and Physics, 2023, https://doi.org/10.1016/j.matchemphys.2023.128015.[2] Ning Zhang, Xiaojing Chen, Jiahao Xu, Pengfei He, Xuli Ding*, Hexagonal Sb nanocrystals As High-Capacity and Long-Cycle Anode Materials for Sodium-Ion Batteries, ACS Applied Materials & Interfaces, 2023, https://doi.org/10.1021/acsamic.3c03340.[3] Jiaojiao Zhao, Jiahao Xu,Qiang Li, Wang Yao, Chujie Yu, Ning Zhang, Xiaojing Chen, Xuli Ding*, BiSbx nanoalloys encapsulated by carbon fibers as high rate sodium ions storage anodes, J. Electroanalytical Chemsitry, 939, 2023, https://doi.org/10.1016/j.jelechem.2023.117452.[4] Ning Zhang, Xiaojing Chen, Jiaojiao Zhao, Pengfei He, Xuli Ding*, Mass Produced Sb/P@C composite nanospheres for adavanced sodium-ions battery anodes, Electrochimica Acta, 2023, https://doi.org/10.1016/j.electacta.2022.141602.[5] Xiaojing Chen, Ning Zhang, Pengfei He, XuliDing*, High-capacity Sb2SnO5 with controlled Sb/Sn phase modulation as advanced anode material fo sodium-ion batteries, J. Alloys and Compounds, 2023, https://doi.org/10.1016/j.jallcom.2022.168472.[6] Jiahao Xu, Jiaojiao Zhao, Ning Zhang, Xiaojing Chen, Xuli Ding*, Improved electrochemical performance of SBA-15 based SiO2 anodes with N-doping porous carbon, J. Electroanalytical Chemistry, 2023, https://doi.org/10.1016/j.jallcom.2022.168472.[7] Hongda Zhao, Xuli Ding*, Ning Zhang, Xiaojing Chen, Jiahao Xu, Pengfei He, Dual mediated SiO particles by graphene cord and phase change for high-performance lithium ions battery anodes, Advanced Materials Interface, 2022, DOI: 10.1002/admi.202102489.[8] Mustafa Khan, Xuli Ding*, Hongda Zhao, Yuxin Wang*, Ning Zhang, Xiaojing Chen, Jiahao Xu, SiO2-based Lithium-ion battery anode materials: A brief review, J. Elec. Mater, 2022, https://doi.org/10.1007/s116664-022-09628-1. [9] Hongda Zhao, Xuli Ding*, Ning Zhang, Xiaojing Chen, Jiahao Xu, Improved electrochemcial performance of silsicon monoxide anode materials prompted by macroporous carbon, J.P. Mater. 2022, https://doi.org/10.1007/s10934-022-01243-z.[10] Mustafa Khan, Xuli Ding*, Hongda Zhao, Yuxin Wang*, Ning Zhang, Xiaojing Chen, Jiahao Xu, Recent advancements in Selenium-based cathode materials for lithium batteries: a mini-review, Electrtochem, 2022, 3, 285-308.[11]. Xuli Ding, Daowei Liang, Xin Ai, Hongda Zhao, Ning Zhang, Xiaojing Chen, Jiahao Xu, Hui Yang, Synergistic Lithium Storage in Silica-Tin Composites Enables a Cycle-Stable and High-Capacity Anode for Lithium-Ion Batteries, ACS Appl. Energy Mater, 4, 3, 2741-2750 (2021).[12]. Xuli Ding, Hongda Zhao, Daowei Liang, Enhanced Electrochemcial Performance of silicon monoxide anode materials promoted by germanium, Materials Chemistry and Physics, 2021, 267, 124611 (2021).[13]. Xuli Ding, Daowei Liang, Hongda Zhao, Enhanced Electrochemical Performance Promoted by Tin in Silica Anode Materials for Stable and High-Capacity Lithium-Ion Batteries, Materials, 14, 1071 (2021). [14]. Mustafa Khan, Xuli Ding*, Hongda Zhao , Xinrong Ma , Yuxin Wang*, Facile Synthesis of Carbon Nanospheres with High Capability to Inhale Selenium Powder for Electrochemical Energy Storage, Materials, 14, 6760 (2021).[15]. Xuli Ding, Yanjie Wang, Bilayer-graphene-coated Si nanoparticles as advanced andoes for high-rate lithium-ion batteries, Electrochimica Acta, 329, 134975 (2020).[16]. Xuli Ding, Yi Liu, Hollow bismuth ferrite combined graphene as advanced anode material for sodium-ion batteries, Progress in Natural Science: Materials International, (2020).[17]. Xuli Ding, Daowei Liang, Yi Liu, Walnut Inspired Silicon Carbon Composites for Stable Lithium Ions Battery Anodes, Materials Science, Composite Materials, 4(1)1-7, (2020).[18]. Xuli Ding, Hong Sun, Layered Phosphorus-Rich Phosphide Composite as a Stable, High-Capacity Anode for Sodium Ion Batteries, ACS Applied Energy Materials, 2, 4309-4315 (2019).[19].Yanjie Wang, Chun Fang, Ying Huang, Qing Liu, Ruirui Zhao, Xuli Ding, Yunhui Huang, Porous carbon adsorption layer enabling highly reversible redox-reaction of a high potential organic electrode material for sodium ion batteries, RSC Advances, 8, 24900-24905 (2018).[20]. Xuli Ding,Haifeng Wang,Xiaoxiao Liu,Zhonghui Gao,Yangyang Huang,Danhui Lv,Pengfei He,Yunhui Huang, Advanced anodes composed of graphene encapsulated nano-silicon in a carbon nanotube network, RSC Adv., 7, 15694-15701 (2017).[21]. Xuli Ding, Yangyang Huang, Guolong Li, Yang Tang, Xiaocheng Li, Yunhui Huang, Phosphorus nanoparticles combined with cubic boron nitride and graphene as stable sodium-ion battery anodes, Electrochimica Acta, 235, 150-157 (2017).[22]. Xuli Ding, XiaoXiao Liu, Yangyang Huang, Xuefu Zhang, Qianjin Zhao, Xinghua Xiang, Guolong Li, Pengfei He, Zhaoyin Wen, Ju Li, Yunhui Huang, Enhanced electrochemical performance promoted by monolayer graphene and void space in silicon composite anode materials, Nano Energy, 27, 647-657 (2016). [23]. Guolong Li , Ze Yang, Yan Jiang, Chuanhong Jin, Wei Huang, Xuli Ding, Yunhui Huang, Towards polyvalent ion batteries: A zinc-ion battery based on NASICON structured Na3V2(PO4)3,Nano Energy, 25, 211-217 (2016).[24]. Xinghua Xiang,Xiaocheng Li,Kongyao Chen,Yang Tang,Min Wan, Xuli Ding, Lihong Xue,Wuxing Zhangand Yunhui Huang,Gamma titanium phosphate as an electrode material for Li-ion and Na-ion storage: performance and mechanism, J. Mater. Chem. A. 4, 18084-18090 (2016).[25]. Yang Tang,Wuxing Zhang,Lihong Xue, Xuli Ding, Ting Wang,Xiaoxiao Liu,Jing Liu,Xiaocheng Liand Yunhui Huang, Polypyrrole-promoted superior cyclability and rate capability of NaFe[Fe(CN)] cathodes for sodium- ion batteries, J. Mater. Chem. A. 4. 6036-6041 (2016). 教学随笔 |