刘丹

发布时间:2019.01.18 13:03

  

 

  

刘丹,男

出生年月:197908

学位: 博士职称: 副教授,硕士生导师

Emaildaniellliu@whut.edu.cn

个人简介:

刘丹,副教授,硕士生导师。于2005年留校任教,20163月至201711月在美国威斯康辛大学(密尔沃基分校)从事博士后研究。主讲《普通化学》、《应用电化学》、《无机化学实验》、《综合实验》和《仪器分析实验》等本科生课程,主讲《精细无机合成》和《化学前沿与进展》等研究生课程,指导国家大学生创新性实验计划。获校级授课竞赛三等奖和校级优秀教案奖,院级授课竞赛一等奖;多次获授课优质优酬;主持教研项目1项;曾获校级先进工作者称号。主要从事多孔材料、碳材料的合成方法学研究以及锂/钠离子电池、锂硫电池、固态电池等储能器件及材料的研究。已在Energy Environ. Sci.Adv. Funct. Mater.SmartMatNano energyChem. Eng. J.J. Mater. Chem. AACS Appl. Mater. InterfacesJ. Power SourceCarbon等期刊发表SCI研究论文100余篇SCI他人引文3300余次H个人引文指数34。主持和参与包括国家自然科学基金等国家级和省、部级项目10余项。

教育经历:

2005/09 – 2011/06,永利集团88304官网,材料物理与化学,博士

2002/09 – 2005/06,永利集团88304官网,应用化学,硕士

1998/09 – 2002/06,永利集团88304官网,精细化工,学士

工作经历:

2016/03 – 2017/11,美国威斯康星大学-密尔沃基分校,博士后

2012/10 至今,永利集团88304官网,永利集团88304官网化学系,副教授

2007/10 – 2012/09,永利集团88304官网,理学院化学系,讲师

2005/07 – 2007/09,永利集团88304官网,理学院化学系,助教

研究领域:

材料化学、多孔材料、碳材料、锂/钠离子电池、锂硫电池、固态电池、超级电容器等

主要科研项目:

1.主持:前驱体材料xxx”2022.09-2024.0930万,经费来源:横向,在研。

2.主持:博康生物-武汉理工手性医药中间体技术研究中心2021.01-2024.12200万,经费来源:横向,在研。

3.主持:异相芬顿反应催化剂2021.04-2024.1222万,经费来源:横向,在研。

4.主持:堆肥法生物可降解测试设备2020.06-2021.065万,经费来源:横向,已结题。

5.主持:孔隙调控和表面转化协同构筑空气稳定、高负载磷碳负极及增强储钠/钾性能2020-IB-0282020.01-2021.12,经费来源:中央高校基本科研业务费专项资金,已结题。

6.主持:低聚倍半硅氧烷自组装合成有序微/介孔碳及其结构调控和电容性能研究(214011452015.01-2017.12,经费来源:国家自然科学基金(青年基金),已结题。

7.主持:长沙继兴页轮胶黏剂物理性能测试与配方优化20131h05412013.12-2014.06,经费来源:横向,已结题。

8.主持:杂多酸基复合介孔材料微观结构测试20141h02052014.04-2014.11,经费来源:横向,已结题。

9.主持:石墨烯包覆过渡金属氧化物的可控合成与能源储存转换应用(2018-IB-0222018.01-2019.12,经费来源:中央高校基本科研业务费专项资金,已结题。

10.主持:倍半硅氧烷与嵌段共聚物自组装构筑有序介/微分级孔碳及其电化学性能研究(2014-Ia-0332014.01-2015.12,经费来源:中央高校基本科研业务费专项资金,已结题。

代表性论文(标记“*”为通讯作者):

在国际国内刊物发表100余篇SCI研究论文,SCI他人引用3300余次,个人引文指数h-index34

1.Li J, Liu D*, Sun H, Qu D, Xie Z, Tang HL, Liu J*. Mixed ion‐electron conducting Li3P for efficient cathode prelithiation of all‐solid‐state Li‐ion batteries. SmartMat 2023, e1200. (IF: 20.4)

2.Song J, Peng X, Liu D*, Li H, Wu M, Fang K, Zhu X, Xiang X, Tang HL*. On-site conversion reaction enables ion-conducting surface on red phosphorus/carbon anode for durable and fast sodium-ion batteries. Journal of Energy Chemistry 2023, 80, 381-391. (IF: 13.1)

3.Liu Z, Tian H, Xu R*, Men W, Su T, Qu Y, Zhao W, Liu D*. Magnetic crystallite-decorated hollow multi-cavity carbon nanosheet spheres for superior electromagnetic absorption. Carbon 2023, 205, 138-150. (IF: 11.307)

4.Liu Z, Tian H, Xu R*, Men W, Su T, Qu Y, Zhao W, Liu D*. Magnetic crystallite-decorated hollow multi-cavity carbon nanosheet spheres for superior electromagnetic absorption. Carbon 2023, 205, 138-150. (IF: 10.9)

5.Li H, Song J, Wu F, Wang R, Liu D*, Tang HL*. Metal-nitrogen-doped hybrid ionic/electronic conduction triple-phase interfaces for high-performance all-solid-state lithium-sulfur batteries. Nano Research 2023, doi: 10.1007/s12274-023-5815-7. (IF: 9.9)

6.Xiang X, Liu D*, Song J, Zhu X, Xie Z, Tang HL, Zheng H*, Qu D*. Chemical prepotassiation enabling high-efficiency and long-life alloy anodes for potassium-ion batteries. Journal of Alloys and Compounds 2023, 960, 170864. (IF: 6.2)

7.Zhou C, Sun H, Wang Q, Grinderslev JB, Liu D*, Yan Y*, Jensen TR*. Highly electrochemically stable Li2B12H12-Al2O3 nanocomposite electrolyte enabling a 3.8 v room-temperature all-solid-state Li-ion battery. Journal of Alloys and Compounds 2023, 938, 168689. (IF: 6.2)

8.Tian H, Liu Z, Xu R*, Qu Y, Zhao W, Wang Y, Liu D*. High-loading magnetic nanocrystals well-dispersed onto carbon nanosheet honeycombs as ultralight and broadband microwave absorbers. Ceramics International 2023, 49 (17), 28901-28912. (IF: 5.2)

9.Zhu XX, Xia FJ, Liu D*, Xiang XY, Wu JS, Lei JH, Li JS, Qu DY, Liu JP*. Crumpling carbon-pillared atomic-thin dichalcogenides and CNTs into elastic balls as superior anodes for sodium/potassium-ion batteries. Advanced Functional Materials 2022, 2207548. (IF: 19)

10.Wu Y, Liu D*, Qu DY, Li J, Xie Z-Z, Zhang X, Chen H, Tang HL*. Porous Oxygen-Deficient TiNb2O7 Spheres Wrapped by Mxene as High-Rate and Durable Anodes for Liquid and All-Solid-State Lithium-Ion Batteries. Chemical Engineering Journal 2022, 438, 135328. (IF: 15.1)

11.Xu R*, Xu D, Zeng Z, Liu D*. CoFe2O4/Porous Carbon Nanosheet Composites for Broadband Microwave Absorption. Chemical Engineering Journal 2022, 427, 130796. (IF: 15.1)

12.Xiang XY, Liu D*, Zhu XX, Wang YY, Qu DY, Xie Z.-Z., Zhang X, Zheng H*. Boosting Interfacial Ion Transfer in Potassium-Ion Batteries via Synergy Between Nanostructured Bi@NC Bulk Anode and Electrolyte. ACS Applied Materials & Interfaces 202214 (30), 34722-34732. (IF: 9.5)

13.Wu M, Liu D*, Qu DY, Lei J, Zhang X, Chen H, Tang HL*. In-Situ Polymerized Composite Polymer Electrolyte with Cesium-Ion Additive Enables Dual-Interfacial Compatibility in All-Solid-State Lithium-Metal Batteries. Journal of Colloid and Interface Science 2022, 615, 627-625. (IF: 9.9)

14.Zeng Z, Xu D, Li M, Liu Z, Xu R*, Liu D*. Confined Transformation of Trifunctional Co2(OH)2CO3 Nanosheet Assemblies into Hollow Porous Co@N-Doped Carbon Spheres for Efficient Microwave Absorption. Journal of Colloid and Interface Science 2022, 622, 625-636. (IF: 9.9)

15.Wang YY, Liu D*, Lei JH, Tang HL, Zhang RM, Zhang X, Qu DY*. Enhanced potassium storage property of copper phosphide anode by simultaneous carbon hybridization and porosity construction. Journal of Power Sources 2022, 544, 231820. (IF: 9.2)

16.Wei YH, Xu CY, He GH, Hua RQ, Xie ZZ, Liu D*, Li X, Zhang RM, Tang HL*, Li JS, Qu DY*. Influence of structural and chemical environmental factors on electrochemical hydrogen storage in carbon materials. Electrochimica Acta 2022, 433, 141223. (IF: 6.6)

17.Wang YY, Qu DY*, Liu D*, Lei JH, Zhang RM, Tang HL, Zhang X. Frogspawn-like P-rich copper phosphides@N-doped carbon as advanced potassium-ion batteries anodes. ACS Applied Energy Materials 2022. (IF: 6.4)

18.Si Y, Jin H, Zhang Q, Xu D, Xu R*, Ding A, Liu D*. Roll-to-Roll Processable MXene-rGo-PVA Composite Films with Enhanced Mechanical Properties and Environmental Stability for Electromagnetic Interference Shielding. Ceramics International 2022, 48 (17), 24898-24905. (IF: 5.2)

19.Liu W, Cai H, Liu D*, Hua R, Gao H, Zhang R, Tang HL*, Li J, Qu DY*. The Impact of a Trace Amount of Water in an Electrolyte on the Performance of Li‐Ion Batteries—an Empirical Kinetic Model Approach. International Journal of Energy Research 2022, 46 (6), 7988-7995. (IF: 4.6)

20.Zhang Q, Xu D, Si Y, Xu R*, Luo B, He S, Liu D*. Ti3C2Tx Mxene Nanosheets Decorated with Magnetic Co Nanoparticles and CoO Nanosheets for Microwave Absorption. ACS Applied Nano Materials 2022, 5 (5), 7175-7186. (IF: 5.9)

21.Yang Y, Zhu J, Wang P, Zeng W, Liu H, Zhang C, Chen Z, Liu D*, Xiao J*, Mu S*. In Situ Implanting Fine ZnSe Nanoparticles into N-Doped Porous Carbon Nanosheets as an Exposed Highly Active and Long-Life Anode for Lithium-Ion Batteries. Journal of Alloys and Compounds 2021, 876, 160135. (IF: 6.2)

22.He X, Liu D*, Qu DY, Li J, Tang HL, Zhang X*, Chen H. Solid-State Fabrication of Cnt-Threaded Fe1-xS@N-Doped Carbon Composite as High-Rate Anodes for Sodium-Ion Batteries and Hybrid Capacitors. Journal of Alloys and Compounds 2021, 159303. (IF: 6.2)

23.He H, Xu XD, Liu D*, Li J, Wei YH, Tang HL, Li JS, Li X, Xie ZZ*, Qu DY*. The Impacts of Nitrogen Doping on the Electrochemical Hydrogen Storage in a Carbon. International Journal of Energy Research 2021, 1-14. (IF: 4.6)

24.Wu M, Liu D*, Qu DY, Xie Z-Z, Li J, Lei J, Tang HL*. 3D Coral-Like LLZO/PVPF Composite Electrolytes with Enhanced Ionic Conductivity and Mechanical Flexibility for Solid-State Lithium Batteries. ACS Applied Materials & Interfaces 2020, 12 (47), 52652-52659. (IF: 9.5)

25.Wang L, Zhu X, Tu K, Liu D*, Tang H, Li J, Li X, Xie Z-Z*, Qu DY*. Synthesis of Carbon-SiO2 Hybrid Layer@SiO2@CNT Coaxial Nanotube and Its Application in Lithium Storage. Electrochimica Acta 2020, 354, 136726. (IF: 6.6)

26.Li, H, Liu D*, Zhu X, Qu DY, Xie Z, Li J, Tang H*, Zheng D, Qu D*. Integrated 3D electrodes based on metal-nitrogen-doped graphitic ordered mesoporous carbon and carbon paper for high-loading lithium-sulfur batteries. Nano Energy 2020, 73, 104763. (IF: 17.6)

27.Zhu X, Li Y, Li R, Tu K, Li J, Xie Z, Lei J, Liu D*, Qu DY*. Self-Assembled N-Doped Carbon with a Tube-in-Tube Nanostructure for Lithium-Sulfur Batteries. Journal of Colloid and Interface Science 2020, 559, 244-253. (IF: 9.9)

28.Fang K, Liu D*, Xiang X, Zhu X, Tang H, Qu DY*, Xie Z, Li J, Qu D*. Air-Stable Red Phosphorus Anode for Potassium/Sodium-Ion Batteries Enabled through Dual-Protection Design. Nano Energy 2020, 69, 104451. (IF: 17.6)

29.Xiang X, Liu D*, Zhu X, Fang K, Zhou K, Tang H, Xie Z, Li J, Zheng H, Qu DY*. Evaporation-Induced Formation of Hollow Bismuth@N-Doped Carbon Nanorods for Enhanced Electrochemical Potassium Storage. Applied Surface Science 2020, 514, 145947. (IF: 6.7)

30.Xie ZZ, Xu CY, Zhou LN, Liu D*, Chen CY, Tang HL, Li JS, Li X, Qu DY*. Hydrogen Ion Supercapacitor Cell Construction and Rational Design of Cell Structure. International Journal of Energy Research 2019, 43 (14), 8439-8446. (IF: 4.6)

31.Xiang X, You X, Liu D*, Liu X, Yang S, Qiu Y, Tang H*, Xie Z, Zheng H, Li J, Li X, Qu D*. A Hybrid Supercapacitor Constructed by Graphene Wrapped Ordered Meso-Porous Si Based Electrode. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2019, 576, 15-21. (IF: 5.2)

32.Wang Y, Zhu X, Liu D*, Tang H*, Luo G, Tu K, Xie Z, Lei J, Li J, Li X, Qu D*. Synthesis of MOF-74-Derived Carbon/ZnCO2O4 Nanoparticles@CNT-Nest Hybrid Material and Its Application in Lithium Ion Batteries. Journal of Applied Electrochemistry 2019, 49 (11), 1103-1112. (IF: 2.9)

33.Liu D, Fang K, You X, Tang H*, Xie Z-z, Li J, Li X, Qu D*. Formation of Thin Layer Graphite Wrapped Meso-Porous Siox and Its Lithium Storage Application. Ceramics International 2019, 45 (18), 24707-24716. (IF: 5.2)

34.Qu D, Xu X, Zhou L, Li W, Wu J, Liu D*, Xie Z-Z, Li J, Tang H*. Electrochemical Hydrogen Storage in Iron Nitrogen Dual-Doped Ordered Mesoporous Carbon. International Journal of Hydrogen Energy 2019, 44 (14), 7326-7336. (IF: 7.2)

35.Qu D, You X, Feng X, Wu J, Liu D*, Zheng D, Xie Z-Z, Qu D, Li J, Tang H*. Lithium Ion Supercapacitor Composed by Si-Based Anode and Hierarchal Porous Carbon Cathode with Super Long Cycle Life. Applied Surface Science 2019, 463, 879-888. (IF: 6.7)

36.Zhu X, Liu D*, Zheng D, Wang G, Huang X, Harris J, Qu D*, Qu D*. Dual Carbon-Protected Metal Sulfides and Their Application to Sodium-Ion Battery Anodes. Journal of Materials Chemistry A 2018, 6 (27), 13294-13301. (IF: 11.9)

37.Zhou L, Liu D*, Li J, Tang H, Xie Z, Qu D*. Electrochemical Hydrogen Storage in a Nitrogen-Doped Uniformed Microporous Carbon. International Journal of Hydrogen Energy 2018, 43 (31), 14096-14102. (IF: 7.2)

38.Liu D, Huang X, Qu D*, Zheng D, Wang G, Harris J, Si J, Ding T, Chen J, Qu D*. Confined Phosphorus in Carbon Nanotube-Backboned Mesoporous Carbon as Superior Anode Material for Sodium/Potassium-Ion Batteries. Nano Energy 2018, 52, 1-10. (IF: 17.6)

39.Liu D, Chen C, Hu Y, Wu J, Zheng D, Xie Z-z*, Wang G, Qu D, Li J, Qu D*. Reduced Graphene-Oxide/Highly Ordered Mesoporous SiOx Hybrid Material as an Anode Material for Lithium Ion Batteries. Electrochimica Acta 2018, 273, 26-33. (IF: 6.6)

40.Huang X, Liu D (共同第一), Guo X, Sui X, Qu D, Chen J*. Phosphorus/Carbon Composite Anode for Potassium-Ion Batteries: Insights into High Initial Coulombic Efficiency and Superior Cyclic Performance. ACS Sustainable Chemistry & Engineering 2018, 6 (12), 16308-16314. (IF: 8.4)

41.Zhou LN, Qu XS*, Zheng D, Tang HL, Liu D*, Qu DY, Xie ZZ, Li JS, Qu DY*. Electrochemical Hydrogen Storage in Facile Synthesized Co@N-Doped Carbon Nanoparticle Composites. ACS Applied Materials & Interfaces 2017, 9 (47), 41332-41338. (IF: 9.5)

42.Liu D, Li YB, Zheng D, Wang GW, Qu DY*, Xie ZZ, Li CL, Lei JH, Qu DY*. Ammonia-Treated Ordered Mesoporous Carbons with Hierarchical Porosity and Nitrogen-Doping for Lithium-Sulfur Batteries. Chemistryselect 2017, 2 (24), 7160-7168. (IF: 2.1)

43.Liu D, Zeng C, Qu D*, Tang HL, Li Y, Su BL*, Qu DY*. Highly Efficient Synthesis of Ordered Nitrogen-Doped Mesoporous Carbons with Tunable Properties and Its Application in High Performance Supercapacitors. Journal of Power Sources 2016, 321, 143-154. (IF: 9.2)

44.Liu D, Hu YY, Zeng C, Qu DY*. Soft-Templated Ordered Mesoporous Carbon Materials: Synthesis, Structural Modification and Functionalization. Acta Physico-Chimica Sinica 2016, 32 (12), 2826-2840. (IF: 10.9)

45.Liu D*, Cheng G, Zhao H, Zeng C, Qu DY, Xiao L, Tang HL, Deng Z, Li Y*, Su BL*. Self-Assembly of Polyhedral Oligosilsesquioxane (POSS) into Hierarchically Ordered Mesoporous Carbons with Uniform Microporosity and Nitrogen-Doping for High Performance Supercapacitors. Nano Energy 2016, 22, 255-268. (IF: 17.6)

46.Liu D, Zheng D, Wang LL, Qu DY*, Xie ZZ, Lei JH, Guo LP, Deng BH, Xiao L, Qu DY*. Enhancement of Electrochemical Hydrogen Insertion in N-Doped Highly Ordered Mesoporous Carbon. Journal of Physical Chemistry C 2014, 118 (5), 2370-2374. (IF: 3.7)

47.Liu D*, Xia LJ, Qu DY, Lei JH, Li Y, Su BL*. Synthesis of Hierarchical Fiberlike Ordered Mesoporous Carbons with Excellent Electrochemical Capacitance Performance by a Strongly Acidic Aqueous Cooperative Assembly Route. Journal of Materials Chemistry A 2013, 1 (48), 15447-15458. (IF: 11.9)

48.Liu D, Lei JH*, Guo LP, Qu DY, Li Y, Su BL. One-Pot Aqueous Route to Synthesize Highly Ordered Cubic and Hexagonal Mesoporous Carbons from Resorcinol and Hexamine. Carbon 2012, 50 (2), 476-487. (IF: 10.9)

49.Liu D, Lei JH*, Guo LP, Deng KJ. A Nanoparticle Assembly Method for the Production of Crystalline Ordered Mesoporous Titanium Oxide/Carbon Composites. Microporous and Mesoporous Materials 2011, 139 (1-3), 87-93. (IF: 5.2)

50.Liu D, Lei JH*, Guo LP, Deng KJ. Simple Hydrothermal Synthesis of Ordered Mesoporous Carbons from Resorcinol and Hexamine. Carbon 2011, 49 (6), 2113-2119. (IF: 10.9)

专利:

1.刘丹, 宋江平, 唐浩林. 一种多硫化磷表面改性的红磷/碳复合材料及其制备方法和应用. CN202211650210.6.

2.刘丹, 黎晶. 一种Li3P晶体粉体的制备方法、Li3P晶体粉体及其应用. 申请号: 202210546644.5.

3.谢智中, 胡宇飞, 刘丹, 屈德宇, 方衎. 一种高容量_高首效的红磷-分子筛模板碳复合负极材料及其制备方法、应用. 公开号: CN112054177A.

4.谢智中, 伍雅荣, 刘丹, 唐浩林。一种高导电率铌酸钛负极材料的制备方法与应用. 公开号: CN113233504A.


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