個人簡介
職 務: 教授 博士/碩士導師
陳君紅教授是在環境能源納米材料及器件研究領域的國際知名學者。在世界頂級期刊上發表高水平學術論文近70篇(包括Advanced Materials, ACS Nano,Energy & Environmental Science, Environmental Science & Technology和Applied Physics Letters等,他引600次)。共申請6項美國專利,其中3項已批准。2009年在美國成立NanoAffix Science LLC公司,致力於科研成果產業化
陳君紅教授在納米顆粒、碳納米管、石墨烯、雜化納米材料以及這些納米材料在可持續性環境和能源套用(氣體感測器、生物感測器、水污染物感測器、太陽能電池、鋰電池)方面取得突出成果,是該領域國際知名的專家。研究成果曾兩次被Advanced Materials期刊選為扉頁(Frontispiece)文章,一次被NANO期刊選為封面文章,並被多家媒體報導,包括Science Daily, US News, PhysOrg, Photonics Online, Nanowerk, Bio-Medicine, EurekAlert, Nanotechnology Now 和the A to Z of Nanotechnology。曾受Nature Chemistry邀請評論關於新型納米氣體感測器的報導。多次應邀在國際知名大學做學術報告,多次組織環境能源納米材料國際研討會,並應邀在國際學術會議上做主題報告。陳君紅教授本人已獲得總額近500萬美元的科研項目資助,主要來自美國國家自然科學基金(NSF, 12個項目)、美國能源部(DOE, 1個項目)、美國環境保護署(EPA, 1個項目)、美國能源部阿貢國家實驗室(Argonne National Laboratory)、美國施樂公司(Xerox Corporation)、米樂電氣製造公司、江森自控公司、威斯康辛州政府、威斯康辛大學系統、和威斯康辛大學密爾沃基分校。曾獲得2008年美國威斯康辛大學密爾沃基分校和2011年該校工學院傑出研究獎。
現為OAtube Nanotechnology 的副主編和 Dataset Papers in Materials Science 的編委, 曾任The Open Plasma Physics Journal編委。頻繁地為40多種國際學術期刊評審論文(Advanced Materials, EES, APL, ACS Nano, JACS等)。曾受邀參加評審多個國家(美國、歐盟、德國、加拿大、荷蘭、韓國、新加坡等)的項目申請報告,其中包括美國國家自然科學基金(NSF)、美國能源部(DOE)、美國空軍研究所(ARO)、美國化學學會石油研究基金(ACS-PRF)、德國國家自然科學基金(DFG)等。
教育背景
· B.E., Thermal Engineering, Tongji University, Shanghai, China, 1995
· M.S., Mechanical Engineering, University of Minnesota, Minneapolis, 2000
· Ph.D., Mechanical Engineering, University of Minnesota, Minneapolis, 2002
專業經歷
Professional Experience
· Postdoctoral Scholar of Chemical Engineering, California Institute of Technology, 2002-2003
· Assistant Professor of Mechanical Engineering, University of Wisconsin-Milwaukee, 2003-2008
· Faculty affiliation, Laboratory for Surface Studies (LSS)-UWM Center of Excellence, 2004-present
· Associate Professor of Mechanical Engineering, University of Wisconsin-Milwaukee, 2008-2011
· Professor of Mechanical Engineering, University of Wisconsin-Milwaukee, 2011-present
發表文章
K. H. Yu, G. H. Lu, Kehung Chen, Shun Mao, Haejune Kim, and J. H. Chen*, "Controllable Photoelectron Transfer in CdSe Nanocrystal-Carbon Nanotube Hybrid Structures," Accepted to Nanoscale, Dec. 2011.
E. C. Mattson, H. H. Pu, S. M. Cui, M. A. Schofield, S. H. Rhim, G. H. Lu, M. J. Nase, R. S. Ruoff, M. Weinert, M. Gajdardziksa-Josifovska, J. H. Chen*, and C. J. Hirschmugl*, "Evidence of Nanocrystalline Semiconducting Graphene Monoxide during Thermal Reduction of Graphene Oxide in Vacuum," Accepted to ACS Nano, Nov. 2011.
S. Mao, H. H. Pu, and J. H. Chen*, "Graphene Oxide and Its Reduction: Modeling and Experimental Progress," Accepted to RSC Advances, Nov. 2011.
S. Q. Ci, Z. H. Wen, J. H. Chen*, and Z. He*, "Bamboo-like Nitrogen-doped Carbon Nanotubes Decorated Anode Electrode for Enhancing Power Generation in Microbial Fuel Cells," Electrochemistry Communications 14(1), 71-74, 2012.
P. X. Wang, F. G. Fan, J. Swift, and J. H. Chen*, "Particle-in-cell and Monte Carlo Collision Simulation of Positive and Negative Corona Discharges," Accepted to IEEE Transactions on Plasma Science, Oct. 2011.
Z. H. Wen, S. M. Cui, H. H. Pu, S. Mao, K. H. Yu, X. L. Feng*, and J. H. Chen*, "Metal Nitride/Graphene Nanohybrids: General Synthesis and Multifunctional Titanium Nitride/Graphene Electrocatalyst," Advanced Materials 23(45), 5445-5450, 2011.
Z. Bo, K. H. Yu, G. H. Lu, S. Mao, and J. H. Chen*, "Uniform Growth of Few-layer Graphene Vertically Standing on Cylindrical Surface at Atmospheric Pressure," Review of Scientific Instruments 82(8), 086116, 2011.
K. H. Yu, G. H. Lu, S. Mao, H. Kim, and J. H. Chen*, "Selective Deposition of CdSe Nanoparticles on Reduced Graphene Oxide to Understand Photoinduced Charge Transfer in Hybrid Nanostructures," ACS Applied Materials & Interfaces 3(7), 2703-2709, 2011.
K. H. Yu, G. H. Lu, Z. Bo, S. Mao, and J. H. Chen*, "Carbon Nanotube with Chemically-bonded Graphene Leaves for Electronic and Optoelectronic Applications," The Journal of Physical Chemistry Letters 2(13), 1556-1562, 2011.
J. Ma*, F. Yu. Z. W. Yuan, and J. H. Chen*, "Diameter-dependent Thermal-oxidative Stability of Single-walled Carbon Nanotubes Synthesized by a Floating Catalytic Chemical Vapor Deposition Method," Applied Surface Science 257(4), 10471-10476, 2011.
G. H. Lu, K. H. Yu, L. E. Ocola, and J. H. Chen*, "Ultrafast Room-Temperature NH3 Sensing with Positively-Gated Reduced Graphene Oxide Field-Effect Transistors," Chemical Communications 47(27), 7761-7763, 2011.
S. Mao, K. H. Yu, S. M. Cui, Z. Bo, G. H. Lu, and J. H. Chen*, "A New Reducing Agent to Prepare Single-layer, High-quality Reduced Graphene Oxide for Device Applications," Nanoscale 3(7), 2849-2853, 2011.
S. Mao, K. H. Yu, G. H. Lu, and J. H. Chen*, "Highly sensitive protein sensor based on thermally-reduced graphene oxide field-effect transistor," Nano Research 4(10), 921-930, 2011.
Z. Bo, K. H. Yu, G. H. Lu, S. M. Cui, S. Mao, and J. H. Chen*, "Vertically-oriented Graphene Sheets Grown on Metallic Wires for Greener Corona Discharges: Lower Power Consumption and Minimized Ozone Emission," Energy & Environmental Science 4(7), 2525-2528, 2011.
K. H. Yu, P. X. Wang, G. H. Lu, K. H. Chen, Z. Bo, and J. H. Chen*, "Patterning Vertically-oriented Graphene Sheets for Nanodevice Applications," The Journal of Physical Chemistry Letters 2(6), 537-542, 2011.
G. H. Lu, S. Park, K. H. Yu, R. S. Ruoff, L. E. Ocola, D. Rosenmann, and J. H. Chen*, "Toward Practical Gas Sensing Using Highly Reduced Graphene Oxide: A New Signal Processing Method to Circumvent Run-to-Run and Device-to-Device Variations," ACS Nano 5(2), 1154-1164, 2011.
Z. Bo, K. H. Yu, G. H. Lu, S. Mao, and J. H. Chen*, "Understanding Growth of Carbon Nanowalls at Atmospheric Pressure Using Normal Glow Discharge Plasma-enhanced Chemical Vapor Deposition," Carbon 49(6), 1849-1858, 2011.
K. H. Yu, Z. Bo, G. H. Lu, S. Mao, S. M. Cui, Y. W. Zhu, X. Q. Chen, R. S. Ruoff, and J. H. Chen*, "Growth of Carbon Nanowalls at Atmospheric Pressure for One-step Gas Sensor Fabrication," Nanoscale Research Letters 6:202, 2011.
B. J. Hansen, H. Chan, J. Lu, G. H. Lu, and J. H. Chen*, "Short-circuit Diffusion Growth of Long Bi-crystal CuO Nanowires," Chemical Physics Letters 504(1-3), 41-45, 2011.