清华大学材料学院吕瑞涛

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吕瑞涛，博士，清华大学材料学院，博士生导师。2017年获国家优秀青年科学基金项目资助。2017年荣获碳材料研究领域重要奖项Brian Kelly Award（全球每年评选一人）。主要从事低维碳基材料缺陷调控及其在清洁能源、分子探测等领域的应用研究。在PNAS、Adv. Mater.等期刊上发表论文90余篇，被引用3218次。有7篇论文入选ESI高被引论文，5篇论文入选为Acc. Chem. Res.、Adv. Mater.等期刊的封面论文。主持国家自然科学基金2项，中国航空工业集团公司委托项目1项。


吕瑞涛博士，助理教授，博士生导师
2014清华大学“学术新人奖”
2016“北京市科技新星计划”
电子邮件：lvruitao@tsinghua.edu.cn
办公室电话：010-62781284


教育背景
1997/09-2001/07 山东轻工业学院 化学工程系 本科
2001/09-2004/03 北京理工大学 材料科学研究中心 硕士
2004/09-2009/01 清华大学 材料科学与工程系 博士


工作履历
2009/01-2011/01 清华大学 材料科学与工程系 博士后
2009/11-2010/08 日本九州大学 先导物质化学研究所 访问研究
2011/01-2013/01 美国宾夕法尼亚州立大学 物理系 博士后
2013/02-2015/12 清华大学 材料学院 助理研究员，硕士生导师
2016/01-至今    清华大学 材料学院 助理教授，博士生导师


研究领域
低维碳基功能材料；二维无机层状材料；新型能源转换/存储材料与器件


研究概况
主要从事二维材料缺陷调控设计、合成及在能源存储/转换器件、超灵敏分子探测、高性能催化等领域的应用性能研究。在PNAS、Adv. Mater.、Acc. Chem. Res.等期刊上发表SCI收录论文80多篇，发表论文被引用3400余次（H-index：30，Google Scholar）。有7篇论文入选ESI高被引论文，5篇论文入选为Acc. Chem. Res.、Adv. Mater.等期刊的封面论文。编写Wiley学术专著1章，申请中国发明专利10项（5项已授权）。担任Adv. Mater.、ACS Nano、Carbon等32个国际期刊的学术审稿人和教育部学位论文评审专家，荣获2015年Excellence in Review Award for service to the journal Carbon。主持完成国家自然科学基金-青年基金项目1项，目前正在承担国家自然科学基金-面上项目1项，中国航空工业集团公司委托项目1项。参加国家重点基础研究发展计划（973计划）项目和973计划-青年科学家专题项目各1项。


奖励与荣誉
2016  北京市科技新星计划
2014  清华大学学术新人奖
2011  清华大学优秀博士后
2010  Elsevier Carbon Journal Prize（Runner-up）
2009  中国材料研讨会（C-MRS）青年优秀论文奖
2009  清华大学优秀博士学位论文二等奖
2007  清华大学综合优秀一等奖（清华之友-康宁奖学金）
2004  北京理工大学优秀硕士学位论文
2004  北京理工大学优秀毕业生


学术成果
学术专著章节：
Florentino Lopez-Urias, Ruitao Lv, Humberto Terrones, Mauricio Terrones. Doped graphene: Theory, synthesis, characterization and applications (Chapter 9 of the Book: "Graphene Chemistry: Theoretical Perspectives"), 2013, Wiley.
部分期刊论文：
[1]  F. Yu, Q. Liu, X. Gan, M. Hu, T. Zhang, C. Li*, F. Kang, M. Terrones*, R. Lv*. Ultrasensitive Pressure Detection of Few-Layer MoS2. Advanced Materials 2016: DOI: 10.1002/adma.201603266.
[2]  X. Wang, X. Gan, T. Hu, K. Fujisawa, Y. Lei, Z. Lin, B. Xu, Z.-H. Huang, F. Kang, M. Terrones*, R. Lv*. Noble-Metal-Free Hybrid Membranes for Highly Efficient Hydrogen Evolution. Advanced Materials 2016: DOI: 10.1002/adma.201603617.
[3]  Q. Wang, X. Zhang*, R. Lv*, X. Chen, B. Xue, P. Liang, X. Huang. Binder-free nitrogen-doped graphene catalyst aircathodes for microbial fuel cells. Journal of Materials Chemistry A 2016, 4: 12387-12391. (Front Cover)
[4]  Z. Lin, B.R. Carvalho, E. Kahn, R. Lv, R. Rao, H. Terrones, M.A. Pimenta, M. Terrones. Defect engineering of two-dimensional transition metal dichalcogenides. 2D Materials 2016, 3: 022002.
[5]  Y. Jia*, Z. Zhang, L. Xiao, R. Lv*. Carbon Nanotube-Silicon Nanowire Heterojunction Solar Cells with Gas-Dependent Photovoltaic Performances and Their Application in Self-Powered NO2 Detecting. Nanoscale Research Letters 2016, 11: 299-299.
[6]  X. Gan, R. Lv*, H. Zhu, L.-P. Ma, X. Wang, Z. Zhang, Z.-H. Huang, H. Zhu, W. Ren, M. Terrones, F. Kang*. Polymer-coated graphene films as anti-reflective transparent electrodes for Schottky junction solar cells. Journal of Materials Chemistry A 2016, 4: 13795-13802.
[7]  S. Feng, M.C. Dos Santos, B.R. Carvalho, R. Lv, Q. Li, K. Fujisawa, A.L. Elias, Y. Lei, N. Perea-Lopez, M. Endo, M. Pan, M.A. Pimenta, M. Terrones. Ultrasensitive molecular sensor using N-doped graphene through enhanced Raman scattering. Science Advances 2016, 2: e1600322.
[8]  Y. Bai, Q. Wang, R. Lv*, H. Zhu, F. Kang. Progress on perovskite-based solar cells. Chinese Science Bulletin 2016, 61: 489-500.
[9]  X. Yu, C. Zhan, R. Lv, Y. Bai, Y. Lin, Z.-H. Huang*, W. Shen, X. Qiu, F. Kang*. Ultrahigh-rate and high-density lithium-ion capacitors through hybriding nitrogen-enriched hierarchical porous carbon cathode with prelithiated nnicrocrystalline graphite anode. Nano Energy 2015, 15: 43-53.
[10]  D.-M. Tang, C.-L. Ren, R. Lv, W.-J. Yu, P.-X. Hou, M.-S. Wang, X. Wei, Z. Xu, N. Kawamoto, Y. Bando, M. Mitome, C. Liu, H.-M. Cheng, D. Golberg. Amorphization and Directional Crystallization of Metals Confined in Carbon Nanotubes Investigated by in Situ Transmission Electron Microscopy. Nano Letters 2015, 15: 4922-4927.
[11]  R. Lv, H. Terrones, A.L. Elias, N. Perea-Lopez, H.R. Gutierrez, E. Cruz-Silva, L.P. Rajukumar, M.S. Dresselhaus, M. Terrones. Two-dimensional transition metal dichalcogenides: Clusters, ribbons, sheets and more. Nano Today 2015, 10: 559-592.
[12]  R. Lv, J.A. Robinson, R.E. Schaak, D. Sun, Y. Sun, T.E. Mallouk, M. Terrones. Transition Metal Dichalcogenides and Beyond: Synthesis, Properties, and Applications of Single- and Few-Layer Nanosheets. Accounts of Chemical Research 2015, 48: 56-64. (Front Cover, ESI highly cited paper, 129 cites)
[13]  R. Lv, G. Chen, Q. Li, A. Mccreary, A. Botello-Mendez, S.V. Morozov, L. Liang, X. Declerck, N. Perea-Lopez, D.A. Culleni, S. Feng, A.L. Elias, R. Cruz-Silva, K. Fujisawa, M. Endo, F. Kang, J.-C. Charlier, V. Meunier, M. Pan, A.R. Harutyunyan, K.S. Novoselov, M. Terrones. Ultrasensitive gas detection of large-area boron-doped graphene. PNAS 2015, 112: 14527-14532.
[14]  X. Gan, R. Lv*, J. Bai, Z. Zhang, J. Wei, Z.-H. Huang, H. Zhu, F. Kang*, M. Terrones*. Efficient photovoltaic conversion of graphene-carbon nanotube hybrid films grown from solid precursors. 2D Materials 2015, 2: 034003.
[15]  R. Lv, M.C. Dos Santos, C. Antonelli, S. Feng, K. Fujisawa, A. Berkdemir, R. Cruz-Silva, A.L. Elias, N. Perea-Lopez, F. Lopez-Urias, H. Terrones, M. Terrones. Large-Area Si-Doped Graphene: Controllable Synthesis and Enhanced Molecular Sensing. Advanced Materials 2014, 26: 7593-7599. (Back Cover)
[16]  R. Lv, E. Cruz-Silva, M. Terrones. Building Complex Hybrid Carbon Architectures by Covalent Interconnections: Graphene-Nanotube Hybrids and More. ACS Nano 2014, 8: 4061-4069.
[17]  N. Perea-Lopez, A.L. Elias, A. Berkdemir, A. Castro-Beltran, H.R. Gutierrez, S. Feng, R. Lv, T. Hayashi, F. Lopez-Urias, S. Ghosh, B. Muchharla, S. Talapatra, H. Terrones, M. Terrones. Photosensor Device Based on Few-Layered WS2 Films. Advanced Functional Materials 2013, 23: 5511-5517.
[18]  N.I. Kovtyukhova, Y. Wang, R. Lv, M. Terrones, V.H. Crespi, T.E. Mallouk. Reversible Intercalation of Hexagonal Boron Nitride with Bronsted Acids. Journal of the American Chemical Society 2013, 135: 8372-8381.
[19]  H.R. Gutierrez, N. Perea-Lopez, A.L. Elias, A. Berkdemir, B. Wang, R. Lv, F. Lopez-Urias, V.H. Crespi, H. Terrones, M. Terrones. Extraordinary Room-Temperature Photoluminescence in Triangular WS2 Monolayers. Nano Letters 2013, 13: 3447-3454.
[20]  A.L. Elias, N. Perea-Lopez, A. Castro-Beltran, A. Berkdemir, R. Lv, S. Feng, A.D. Long, T. Hayashi, Y.A. Kim, M. Endo, H.R. Gutierrez, N.R. Pradhan, L. Balicas, T.E. Mallouk, F. Lopez-Urias, H. Terrones, M. Terrones. Controlled Synthesis and Transfer of Large-Area WS2 Sheets: From Single Layer to Few Layers. ACS Nano 2013, 7: 5235-5242.
[21]  T. Cui, R. Lv*, Z.-H. Huang, X. Gan, K. Wang, D. Wu, H. Zhu, F. Kang*. Hybrid graphene/amorphous carbon films with tadpole-like structures for high-performance photovoltaic applications. RSC Advances 2013, 3: 22295-22300.
[22]  T. Cui, R. Lv*, Z.-H. Huang, S. Chen, Z. Zhang, X. Gan, Y. Jia, X. Li, K. Wang, D. Wu, F. Kang*. Enhanced efficiency of graphene/silicon heterojunction solar cells by molecular doping. Journal of Materials Chemistry A 2013, 1: 5736-5740.
[23]  H. Terrones, R. Lv, M. Terrones, M.S. Dresselhaus. The role of defects and doping in 2D graphene sheets and 1D nanoribbons. Reports on Progress in Physics 2012, 75: 062501. (230 cites)
[24]  R. Lv, M. Terrones. Towards new graphene materials: Doped graphene sheets and nanoribbons. Materials Letters 2012, 78: 209-218. (126 cites)
[25]  R. Lv, Q. Li, A.R. Botello-Mendez, T. Hayashi, B. Wang, A. Berkdemir, Q. Hao, A.L. Elias, R. Cruz-Silva, H.R. Gutierrez, Y.A. Kim, H. Muramatsu, J. Zhu, M. Endo, H. Terrones, J.-C. Charlier, M. Pan, M. Terrones. Nitrogen-doped graphene: beyond single substitution and enhanced molecular sensing. Scientific Reports 2012, 2: 586. (ESI highly cited paper, 301 cites)
[26]  R. Lv, T. Cui, M.-S. Jun, Q. Zhang, A. Cao, D.S. Su, Z. Zhang, S.-H. Yoon, J. Miyawaki, I. Mochida, F. Kang. Open-Ended, N-Doped Carbon Nanotube-Graphene Hybrid Nanostructures as High-Performance Catalyst Support. Advanced Functional Materials 2011, 21: 999-1006. (ESI highly cited paper, 213 cites)
[27]  R. Lv, F. Kang, J. Gu, K. Wang, D. Wu. Synthesis, field emission and microwave absorption of carbon nanotubes filled with ferromagnetic nanowires. Science China-Technological Sciences 2010, 53: 1453-1459.
[28]  R. Lv, S. Tsuge, X. Gui, K. Takai, F. Kang, T. Enoki, J. Wei, J. Gu, K. Wang, D. Wu. In situ synthesis and magnetic anisotropy of ferromagnetic buckypaper. Carbon 2009, 47: 1141-1145.
[29]  R. Lv, F. Kang, D. Zhu, Y. Zhu, X. Gui, J. Wei, J. Gu, D. Li, K. Wang, D. Wu. Enhanced field emission of open-ended, thin-walled carbon nanotubes filled with ferromagnetic nanowires. Carbon 2009, 47: 2709-2715.
[30]  R. Lv, L. Zou, X. Gui, F. Kang, Y. Zhu, H. Zhu, J. Wei, J. Gu, K. Wang, D. Wu. High-yield bamboo-shaped carbon nanotubes from cresol for electrochemical application. Chemical Communications 2008: 2046-2048.
[31]  R. Lv, F. Kang, J. Gu, X. Gui, J. Wei, K. Wang, D. Wu. Carbon nanotubes filled with ferromagnetic alloy nanowires: Lightweight and wide-band microwave absorber. Applied Physics Letters 2008, 93: 223105. (95 cites)
[32]  R. Lv, F. Kang, D. Cai, C. Wang, J. Gu, K. Wang, D. Wu. Long continuous FeNi nanowires inside carbon nanotubes: Synthesis, property and application. Journal of Physics and Chemistry of Solids 2008, 69: 1213-1217.
[33]  R. Lv, F. Kang, W. Wang, J. Wei, X. Zhang, Z. Huang, J. Gu, K. Wang, D. Wu. Soft magnetic performance improvement of Fe-filled carbon nanotubes by water-assisted pyrolysis route. Physica Status Solidi A-Applications and Materials Science 2007, 204: 867-873.
[34]  R. Lv, F. Kang, W. Wang, J. Wei, J. Gu, K. Wang, D. Wu. Effect of using chlorine-containing precursors in the synthesis of FeNi-filled carbon nanotubes. Carbon 2007, 45: 1433-1438.
[35]  R. Lv, A. Cao, F. Kang, W. Wang, J. Wei, J. Gu, K. Wang, D. Wu. Single-crystalline permalloy nanowires in carbon nanotubes: Enhanced encapsulation and magnetization. Journal of Physical Chemistry C 2007, 111: 11475-11479.
[36]  R.T. Lv, C.B. Cao, H. Zhu. Synthesis and characterization of ZnS nanowires by AOT micelle-template inducing reaction. Materials Research Bulletin 2004, 39: 1517-1524.
[37]  R.T. Lv, C.B. Cao, H.Z. Zhai, D.Z. Wang, S.Y. Liu, H.S. Zhu. Growth and characterization of single-crystal ZnSe nanorods via surfactant soft-template method. Solid State Communications 2004, 130: 241-245. (62 cites)
[38]  R.T. Lv, C.B. Cao, Y.J. Guo, H.S. Zhu. Preparation of ZnS nanotubes via surfactant micelle-template inducing reaction. Journal of Materials Science 2004, 39: 1575-1578.

heqinan

清华大学材料学院吕瑞涛研究组在Materials Today上在线发表长篇综述文章“Heterogeneous electrocatalysts design for nitrogen reduction reaction under ambient conditions”。该论文系统总结了近几年常温常压氮气还原合成氨的研究进展并指出了该领域目前面临的主要挑战，提出通过异相催化剂的设计对其性能进行调控，实现氮气-氨的高效转化。

该综述基于实验研究与理论计算的有机结合，细致探讨了晶面调控、形貌工程、缺陷调控等材料设计策略对催化剂性能的影响，并系统总结了材料设计策略在贵金属催化剂、过渡金属基催化剂、单原子催化剂及非金属催化剂的应用，具体从材料合成、结构表征、性质调控及性能优化等方面系统展开讨论，建立形貌/缺陷调控、材料结构及催化性质三者之间的联系，为高活性、高选择性以及高稳定性的氮还原电催化材料的研发提供新思路。

清华大学材料学院吕瑞涛研究组致力于低维材料的缺陷调控和应用性能研究，在碳材料和二维材料的环境污染物探测、清洁能源等领域的应用方面取得了一系列研究成果。

《Materials Today》是国际材料科学研究领域的知名综述性学术期刊（影响因子：24.537），主要刊登在材料科学与工程领域最新研究进展的评述论文及重要的原创性研究论文，每年出版10期。

文献链接：

Yuchi Wan, Jichu Xu, Ruitao Lv*, Heterogeneous electrocatalysts design for nitrogen reduction reaction under ambient conditions. Mater. Today, 2019: doi.org/10.1016/j.mattod.2019.03.002.

https://doi.org/10.1016/j.mattod.2019.03.002