潘曹峰 男 国家纳米科学中心
电子邮件:pcf.tsinghua@gmail.com
通信地址:北京市海淀区双清路18号
邮政编码:

研究领域

   
1.压电光电子学效应及其在光电子器件中的应用
        压电效应是压电材料,如氧化锌、氮化镓、锆钛酸铅等,在应力作用下产生形变时出现的一种内部电势的现象。压电效应已经广泛应用于微机械传感、器件驱动和能源领域。对于氧化锌、氮化镓等半导体材料,由于同时具有压电性和半导体性,压电效应可以改变金属-半导体的界面势垒和p-n结的输运性质,这就是压电电子学。如果器件在源极或漏极中有一端或两端是肖特基接触的,当激光照射在源极或漏极时,由于压电效应、光激发和半导体特性的三相耦合,可以产生一种新的效应,即压电光电子学效应。压电光电子学可以利用压电电场来调控载流子的产生、传输、分离和复合,在发光二极管、光探测和太阳能电池等领域中都有广泛的应用。最近,我们已经实现以应变调控发光二极管的发光强度和发光效率,以应变来提高光探测的效率;以及用应变来调控太阳能电池的性能。我们正在利用这一效应构建新一代自驱动纳米传感器系统。 

代表作:
1) Pan, C. F.; Niu, S.M.; Ding, Y.; Dong, L.; Yu, R. M.; Liu, Y.; Zhu, G. and Wang, Z. L, Enhanced Cu2S/CdS coaxial nanowire solar cells by piezo-phototronic effect, Nano Letters, online
2.纳米发电机及“混合”纳米发电机及其在自驱动纳米系统中的应用
        纳米技术作为21世纪的一个重要新兴科技领域,在理论与实践上正经历着高速的发展。大量新型纳米材料与器件不断被开发出来,并在生物医学、国防以及人们日常生活的各个领域中展现出前所未有的应用前景。然而,纳米技术发展到今日,大量的研究都集中于开发高灵敏度,高性能的纳米器件,很少有关于纳米尺度的电源系统研究。但是,应用于生物及国防等方面的纳米传感器对这种电源系统的需求却与日俱增。如果这些传感器能从环境中自己给自己提供电源,从而实现器件和电源的同时小型化,将是极具意义的。之前,我们课题已经研究出了基于氧化锌纳米线的纳米发电机,能够将环境中的机械能转化为电能。
        我们生活的环境中还充满了其它各种各样的能量, 如肌肉活动能、化学能、生物能、微风能、太阳能、热能等。如果我们能够制造一个纳米器件,能够同时或者独立地利用环境中的多种能量,产生电能,那将是非常有意义的。我们之前的工作中已经研究了利用机械能/太阳能,和机械能/生物化学能的两种混合纳米发电机,并且这两种混合发电机在自驱动纳米系统中的应用。 

代表作:
1) Pan, C. F.; Guo, W. X.; Dong, L.; Zhu, G. and Wang, Z. L, Optical-fiber based core-shell coaxially structured hybrid cell for self-powered nanosystems, 2012, Advanced Materials, online.
2) Pan, C. F.; Li, Z. T.; Guo, W. X.; Zhu, J.; and Wang, Z. L, Fiber-based hybrid nanogenerators for/as self-powered systems in bio-liquid, Angewandte Chemie International Edition, 2011, 50, 11192-11196.
3.纳米线太阳能电池及其在自驱动纳米系统中的应用
        如今,能源已经成为限制人类社会发展的一个最关键的问题。由于石油、煤等能源的不可再生,全人类都在努力寻找新的“可再生”的“绿色”替代能源,如风能、核能和氢能,以维持人类社会的可持续发展。太阳能是一种清洁的、可再生的、用之不尽取之不竭的能源,目前在美国、日本和以色列等国家,已经大量使用太阳能装置,更朝商业化的目标前进。如何降低太阳能电池的成本,提高太阳能电池的能量转换效率是目前研究中急待解决的问题。
        纳米线材料由于其大的表面/体积比,大的长径比,其具有很多优异的物理性能,被认为有望提升太阳能电性能并降低成本。我们利用金属催化腐蚀的方法,在硅晶片表面得到大面积的硅纳米线阵列,该硅纳米线阵列具有很好的减反射性能。我们还利用超高真空物理气相沉积制备了大面积的硅-硅锗单晶外延芯-壳结构纳米线阵列,并制备出太阳能电池,其能量转化效率为3.26%。 

代表作:
Pan, C. F.; Luo, Z. X.; Xu, C.; Luo, J.; Liang, R. R.; Zhu, G.; Wu, W. Z.; Guo, W. X.; Yan, X. X.; Xu, J.; Wang, Z. L.; Zhu, J., Wafer-Scale High-Throughput Ordered Arrays of Si and Coaxial Si/Si1-xGex Wires: Fabrication, Characterization and Photovoltaic Application. ACS Nano 2011, 5 (8), 6629-6636.
4.纳米燃料电池和纳米生物燃料电池及其在自驱动纳米系统中的应用
        随着纳米科学与技术的发展,利用纳米材料的独特性能,已经开发出大量功能强大的纳米器件,如纳米生物传感器、可植入体内的实时医疗监控器、血糖检测传感器等。这些器件体积小、耗能小,而且功能强大、智能化程度高,但是这些纳米器件也需外部能源的供给才能工作。为了给这些纳米尺度的微小器件提供电能,我们需要设计小体积、可持续、稳定的,能长期持久工作的、便于维护的、尺寸与功率与纳米器件相匹配的纳米能源。这些微小的纳米能源一旦研制成功,应用前景将非常广阔。
        我们已经成功合成出质子传导纳米线(Nafion纳米线),并且发现由于分子结构在合成纳米线的过程中发生了重排,该纳米线具有远优于块体的质子传导性能。利用这些质子传导纳米线,我们已经制备出了纳米尺度的燃料电池和生物燃料电池,并且实现了利用这些纳米燃料电池和纳米生物燃料电池来驱动纳米器件。 

代表作:
1) Pan, C. F.; Fang, Y.; Wu, H.; Ahmad, M.; Luo, Z. X.; Li, Q. A.; Xie, J. B.; Yan, X. X.; Wu, L. H.; Wang, Z. L.; Zhu, J., Generating Electricity from Biofluid with a Nanowire-Based Biofuel Cell for Self-Powered Nanodevices. Advanced Materials 2010, 22 (47), 5388-5392. 
2) Pan, C. F.; Wu, H.; Wang, C.; Wang, B.; Zhang, L.; Cheng, Z. D.; Hu, P.; Pan, W.; Zhou, Z. Y.; Yang, X.; Zhu, J., Nanowire-based high performance "micro fuel cell": One nanowire, one fuel cell. Advanced Materials 2008, 20 (9), 1644-1648. 
3) Pan, C. F.; Luo, J.; Zhu, J., From Proton Conductive Nanowires to Nanofuel Cells: A powerful Candidate Generating Electricity for Self-Powered Nanosystems. Nano Research 2011, online publication. 
4) 潘曹峰,朱静,基于单根纳米线的纳米燃料电池研究进展,科学通报,53(21),2008,2671(邀稿,中文核心)

招生信息

   
招生专业
080501-材料物理与化学
080903-微电子学与固体电子学
080901-物理电子学
招生方向
压电光电子学效应及其在光电子器件中的应用
纳米发电机及“混合”纳米发电机及其在自驱动纳米系统中的应用
纳米线太阳能电池及其在自驱动纳米系统中的应用

教育背景

2005-09--2010-07 清华大学 工学博士

工作经历

   
工作简历
2010-08--2012-08 Georgia Institute of Technology 博士后

专利与奖励

   
奖励信息
(1) 北京市优秀博士论文奖,一等奖,省级,2011
(2) 清华大学优秀博士论文,二等奖,研究所(学校)级,2010
专利成果
(1) 一种生物化学纳米发电机及其制备方法,发明,2010,第1作者,专利号:201010163517.4

出版信息

   
发表论文
(1) Optical-fiber based core-shell coaxially structured hybrid cell for self-powered nanosystems,Advanced Materials,2012,第1作者
(2) Rectangular Bunched Rutile TiO2 Nanorod Arrays Grown on Carbon Fiber for Dye-Sensitized Solar Cells,Journal of the American Chemical Society,2012,第5作者
(3) Enhanced Cu2S/CdS coaxial nanowire solar cells by piezo-phototronic effect,Nano Letters,2012,第1作者
(4) Piezotronic effect on the transport property of GaN nanobelt for active flexible electronics,Advanced Materials,2012,第3作者
(5) Hybrid Cells for Simultaneously Harvesting Multi-type Energies for Self-Powered Micro/Nanosystems,Nano Energy ,2012,第2作者
(6) From Proton Conductive Nanowires to Nanofuel Cells: A powerful Candidate Generating Electricity for Self-Powered Nanosystems ,Nano Research ,2011,第1作者
(7) Fiber-based hybrid nanogenerators for/as self-powered systems in bio-liquid,Angewandte Chemie International Edition,2011,第1作者
(8) Wafer-Scale High-Throughput Ordered Arrays of Si and Coaxial Si/Si1-xGex Wires: Fabrication, Characterization and Photovoltaic Application,ACS Nano ,2011,第1作者
(9) Generating Electricity from Biofluid with a Nanowire-Based Biofuel Cell for Self-Powered Nanodevices. ,Advanced Materials,2010,第1作者
(10) Highly Sensitive Amperometric Cholesterol Biosensor Based on Pt-Incorporated Fullerene-like ZnO Nanospheres,Journal of Physical Chemistry C ,2010,第2作者
(11) Investigation of Hydrogen Storage Capabilities of ZnO-Based Nanostructures,Journal of Physical Chemistry C ,2010,第3作者
(12) Controlled synthesis and methanol sensing capabilities of Pt-incorporated ZnO nanospheres,Electrochimica Acta,2010,第3作者
(13) Effect of Pb-doping on the morphology, structural and optical properties of ZnO nanowires synthesized via modified thermal evaporation,Materials Science and Engineering B ,2010,第2作者
(14) Electron irradiation effect and photoluminescence properties of ZnO-tetrapod nanostructures,Materials Chemistry and Physics,2010,第2作者
(15) A Single ZnO Nanofiber-Based Highly Sensitive Amperometric Glucose Biosensor,Journal of Physical Chemistry C ,2010,第2作者
(16) Electrochemical determination of L-Cysteine by an elbow shaped, Sb-doped ZnO nanowire-modified electrode,Journal of Materials Chemistry ,2010,第2作者
(17) Bulk synthesis route of the oriented arrays of tip-shape ZnO nanowires and an investigation of their sensing capabilities,Chemical Physics Letters ,2009,第2作者
(18) The syntheses, properties and applications of Si, ZnO, metal, and heterojunction nanowires,Journal of Materials Chemistry,2009,第1作者
(19) One-step synthesis route of the aligned and non-aligned single crystalline alpha-Si3N4 nanowires,Science in China Series E-Technological Sciences ,2009,第4作者
(20) Ordered arrays of high-quality single-crystalline alpha-Si3N4 nanowires: Synthesis, properties and applications,Journal of Crystal Growth ,2009,第3作者
(21) Nanowire-based high performance micro fuel cell: One nanowire, one fuel cell,Advanced Materials,2008,第1作者
(22) Effect of anneal pre-treatment of polycrystalline aluminum sheets on synthesis of highly-ordered anodic aluminum oxide membranes,Science in China Series E-Technological Sciences ,2008,第3作者
(23) 基于单根纳米线的纳米燃料电池研究进展,科学通报,2008,第1作者
(24) Capping modes in PVP-directed silver nanocrystal growth: Multi-twinned nanorods versus single-crystalline nano-hexapods,Crystal Growth Design ,2008,第4作者
(25) Growth mechanism and optimized parameters to synthesize Nafion-115 nanowire arrays with anodic aluminium oxide membranes as templates,Chinese Physics Letters ,2008,第2作者
(26) Surface decoration of anodic aluminium oxide in synthesis of Nafion (R)-115 nanowire arrays,Nanotechnology ,2007,第1作者
(27) Nano-porous anodic aluminium oxide membranes with 6-19 nm pore diameters formed by a low-potential anodizing process,Nanotechnology,2007,第3作者
(28) Synthesis and characterization of Nafion (R)-115 nanowire arrays, Nanotechnology,2005,第2作者

科研活动

   
参与会议
(1) Fiber-based hybrid nanogenerators for/as self-powered systems in bio-liquid,2011-12,Pan, C. F.; Zhu, J. and Wang, Z. L
(2) Wafer-Scale High-Throughput Ordered Arrays of Si and Coaxial Si/Si1-xGex Wires: Fabrication, Characterization and Photovoltaic Application,2011-12,Pan, C. F.; Zhu, J. and Wang, Z. L.
(3) Generating electricity from biofluid with a nanowire-based biofuel cell for self-powered nanodevices,2011-12,Pan, C. F.; Zhu, J. and Wang, Z. L
(4) Nanofuel cells and nanomechanics,2009-01,Pan, C. F. and Zhu, J
(5) Nanofuel cells: Towards self-powered nanosystems,2009-01,Pan, C. F. and Zhu, J
(6) Nanofuel Cells: Towards Self-powered nanosystems,2009-01,Pan, C. F. and Zhu, J.,
(7) High Performance Nanowire-Based Nanofuel cells,,2008-01,Pan, C. F. and Zhu, J
(8) High performance nano fuel cell based on 1D nano proton transport channels,2007-01,Pan, C. F. and Zhu, J