柳鹏 副研究员
清华大学物理系
纳米中心205
北京 100084
pengliu@tsinghua.edu.cn
个人简历 |
教育背景: 2001-09 至 2007-06, 清华大学, 凝聚态物理, 博士 1997-09 至 2001-06, 武汉大学, 物理学, 学士 工作经历: 2012-12 至 今, 清华大学物理系, 副研究员
2010-07 至 2012-12, 清华大学物理系, 助理研究员
2007-07 至 2010-07, 清华大学材料科学与工程系,博士后 |
研究领域 |
低维碳纳米材料电子学。 开展了以下方面系列研究: 1. 电场催化可控制备低维碳纳米材料 2. 电子与低维碳纳米材料作用 3. 低维碳纳米材料真空电子学 通过电场催化的方法制备了高纯半导体碳管(CNT)阵列;发展了快速表征大面积二维材料晶体结构的低能量透射衍射成像方法,适合表征吸附结构;研究了单根手性指数确定的CNT电子发射和高温输运,研制的CNT场发射中和器成功在轨工作,提出了可实现无次生发射的CNT阵列“电子黑体”阳极以及可同时提高电子透过率和电场均匀性CNT膜栅极,制备的CNT光源应用于温室气体监测。部分成果发表在Nat Catal, Nat Comm, Sci Adv, Nat Rev Electr Eng, PNAS, AM, AFM等杂志。 主持及参加国家自然科学基金和科技部重点研发计划项目多项。 |
[1] P. Liu, Super-aligned carbon nanotube neutralizers for aerospace. Nature Reviews Electrical Engineering 2024, 1 (2), 73-74.
[2] K. Zhang; G. Chen; S. Zhou; Z. Yuan; X. Gu; D. Zhou; Y. Wang; X. Gao; Y. Ma; R. Xu; Z. Bai; P. Liu; L. Yang; S. Zhou; S. Fan; K. Jiang, Carbon nanotube electron blackbody and its radiation spectra. P Natl Acad Sci USA 2023, 120 (6), e2209670120.
[3] L. W. Lai; P. Liu; D. L. Zhou; Q. Q. Li; S. S. Fan; W. Lu, Rapidly Modulated Wide-Spectrum Infrared Source Made of Super Aligned Carbon Nanotube Film for Greenhouse Gas Monitoring. Adv Funct Mater 2022, 33, 2208891.
[4] W. Zhao; Y. Zhang; X. Wang; H. Lu; G. Liu; J. Wei; Z. Shan; P. Liu; K. Jiang; S. Fan, Carbon-nanotube-templated carbon nanofibers with improved mechanical performance. J Appl Phys 2021, 129, 044303.
[5] Y. Pan; P. Ying; Y. Gao; P. Liu; K. Tong; D. Yu; K. Jiang; W. Hu; B. Li; B. Liu; Z. Zhao; J. He; B. Xu; Z. Liu; Y. Tian, Extreme mechanical anisotropy in diamond with preferentially oriented nanotwin bundles. P Natl Acad Sci USA 2021, 118 (47), e2108340118.
[6] W. Ning; P. Lei; S. Lv; Y. Luo; W. Zhao; X. Yang; Q. Li; D. Zhou; P. Liu; Q. Cai; L. Liu; L. Zhang; J. Wang; Q. Li; S. Fan; K. Jiang, High-temperature epitaxial graphite deposition on macroscopic superaligned carbon nanotube structures by a one-step self-heating method. Carbon 2021, 171, 837-844.
[7] Z. B. Liu; J. T. Wang; K. Zhang; X. Y. Gao; P. Liu; Q. Q. Li; L. N. Zhang; S. S. Fan; J. Kong; K. L. Jiang, Toward an Intelligent Synthesis: Monitoring and Intervening in the Catalytic Growth of Carbon Nanotubes. J Am Chem Soc 2021, 143 (42), 17607-17614.
[8] 柳鹏; 周段亮; 张春海; 潜力; 王昱权; 马丽永; 郭雪伟; 王福军; 姜开利; 范守善; 贺建武; 康琦, 超顺排碳纳米管场发射电子源在射频离子微推进中和器中的应用. 真空电子技术 2020, (04), 23-27.
[9] X. H. Yang; X. H. Wang; P. Liu; J. T. Wang; L. N. Zhang; X. Jin; Z. B. Liu; Q. Q. Li; S. S. Fan; K. L. Jiang, The Influence of Carbon Nanotube's Conductivity and Diameter on Its Thermionic Electron Emission. Phys Status Solidi A 2020, 217 (15), 2000069.
[10] X. H. Yang; P. Liu; X. H. Wang; J. T. Wang; L. N. Zhang; X. Jin; S. W. Lv; Y. Wu; Q. Q. Li; S. S. Fan; K. L. Jiang, Optical Phonon Scattering Dominated Transport in Individual Suspended Carbon Nanotubes. Phys Status Solidi B 2020, 257 (9), 2000103.
[11] X. H. Yang; P. Liu; D. L. Zhou; F. Gao; X. H. Wang; S. W. Lv; Z. Yuan; X. Jin; W. Zhao; H. M. Wei; L. Zhang; J. D. Gao; Q. Q. Li; S. S. Fan; K. L. Jiang, High temperature performance of coaxial h-BN/CNT wires above 1,000 degrees C: Thermionic electron emission and thermally activated conductivity. Nano Res 2019, 12 (8), 1855-1861.
[12] J. T. Wang; X. Jin; Z. B. Liu; G. Yu; Q. Q. Ji; H. M. Wei; J. Zhang; K. Zhang; D. Q. Li; Z. Yuan; J. C. Li; P. Liu; Y. Wu; Y. Wei; J. P. Wang; Q. Q. Li; L. Zhang; J. Kong; S. S. Fan; K. L. Jiang, Growing highly pure semiconducting carbon nanotubes by electrotwisting the helicity. Nat Catal 2018, 1 (5), 326-331.
[13] W. Ning; Z. H. Wang; P. Liu; D. L. Zhou; S. Y. Yang; J. Wang; Q. Q. Li; S. S. Fan; K. L. Jiang, Multifunctional super-aligned carbon nanotube/polyimide composite film heaters and actuators. Carbon 2018, 139, 1136-1143.
[14] P. Liu; D. L. Zhou; C. H. Zhang; X. H. Yang; L. Liu; L. N. Zhang; K. L. Jiang; Q. Q. Li; S. S. Fan, Carbon Nanotube Film Gate in Vacuum Electronic Devices. Nano Lett 2018, 18 (8), 4691-4696.
[15] P. Liu; D. L. Zhou; C. H. Zhang; H. M. Wei; X. H. Yang; Y. Wu; Q. W. Li; C. H. Liu; B. C. Du; L. Liu; K. L. Jiang; S. S. Fan, Crystalline multiwall carbon nanotubes and their application as a field emission electron source. Nanotechnology 2018, 29 (34), 345601.
[16] L. J. Jiang; J. L. Wang; P. Liu; W. Song; B. L. He, Study of water adsorption on graphene edges. Rsc Adv 2018, 8 (20), 11216-11221.
[17] L. J. Jiang; P. Liu; L. Zhang; C. H. Liu; L. W. Zhang; S. S. Fan, The adsorption state and the evolution of field emission properties of graphene edges at different temperatures. Rsc Adv 2018, 8 (56), 31830-31834.
[18] W. Zhao; B. Y. Xia; L. Lin; X. Y. Xiao; P. Liu; X. Y. Lin; H. L. Peng; Y. M. Zhu; R. Yu; P. Lei; J. T. Wang; L. N. Zhang; Y. Xu; M. W. Zhao; L. M. Peng; Q. Q. Li; W. H. Duan; Z. F. Liu; S. S. Fan; K. L. Jiang, Low-energy transmission electron diffraction and imaging of large-area graphene. Sci Adv 2017, 3 (9), e1603231.
[19] J. T. Wang; P. Liu; B. Y. Xia; H. M. Wei; Y. Wei; Y. Wu; K. Liu; L. N. Zhang; J. P. Wang; Q. Q. Li; S. S. Fan; K. L. Jiang, Observation of Charge Generation and Transfer during CVD Growth of Carbon Nanotubes. Nano Lett 2016, 16 (7), 4102-4109.
[20] P. Liu; D. L. Zhou; Y. Wei; K. L. Jiang; J. P. Wang; L. N. Zhang; Q. Q. Li; S. S. Fan, Load Characteristics of a Suspended Carbon Nanotube Film Heater and the Fabrication of a Fast-Response Thermochromic Display Prototype. Acs Nano 2015, 9 (4), 3753-3759.
[21] F. Zhu; X. Y. Lin; P. Liu; K. L. Jiang; Y. Wei; Y. Wu; J. P. Wang; S. S. Fan, Heating graphene to incandescence and the measurement of its work function by the thermionic emission method. Nano Res 2014, 7 (4), 553-560.
[22] X. Y. Lin; P. Liu; Y. Wei; Q. Q. Li; J. P. Wang; Y. Wu; C. Feng; L. N. Zhang; S. S. Fan; K. L. Jiang, Development of an ultra-thin film comprised of a graphene membrane and carbon nanotube vein support. Nat Commun 2013, 4.
[23] P. Liu; Y. Wei; L. Liu; K. L. Jiang; S. S. Fan, Formation of free-standing carbon nanotube array on super-aligned carbon nanotube film and its field emission properties. Nano Res 2012, 5 (6), 421-426.
[24] P. Liu; Y. Wei; K. Liu; L. Liu; K. L. Jiang; S. S. Fan, New-Type Planar Field Emission Display with Superaligned Carbon Nanotube Yarn Emitter. Nano Lett 2012, 12 (5), 2391-2396.
[25] H. Y. Hao; P. Liu; J. Tang; Q. Cai; S. S. Fan, Secondary electron emission in a triode carbon nanotube field emission display and its influence on the image quality. Carbon 2012, 50 (11), 4203-4208.
[26] P. Liu; L. A. Liu; K. L. Jiang; S. S. Fan, Carbon-Nanotube-Film Microheater on a Polyethylene Terephthalate Substrate and Its Application in Thermochromic Displays. Small 2011, 7 (6), 732-736.
[27] P. Liu; K. L. Jiang; Y. Wei; K. Liu; L. A. Liu; S. S. Fan, Field emission behavior study of multiwalled carbon nanotube yarn under the influence of adsorbents. J Vac Sci Technol B 2010, 28 (4), 736-739.
[28] P. Liu; L. Liu; Y. Wei; K. Liu; Z. Chen; K. L. Jiang; Q. Q. Li; S. S. Fan, Fast High-Temperature Response of Carbon Nanotube Film and Its Application as an Incandescent Display. Adv Mater 2009, 21 (35), 3563-3566.
[29] P. Liu; Q. Sun; F. Zhu; K. Liu; K. Jiang; L. Liu; Q. Li; S. Fan, Measuring the work function of carbon nanotubes with thermionic method. Nano Lett 2008, 8 (2), 647-651.
