航空航天学院关于浙江大学名誉教授受聘仪式暨��u(Iijima)教授学术演讲会的通知

发布日期:2010-10-08来源:航空航天学院作者:系统管理员访问量:4991

  应浙江大学理学院和航空航天学院邀请,碳纳米管发现者----日本名城大学�岛澄男(Sumio Iijima)教授即将访问浙江大学。我校将举行�岛教授受聘浙江大学名誉教授仪式。受聘仪式后,�岛教授将为我校师生作专题学术报告。

 
  具体活动安排:
  一、 时间:10月11日下午15:00
  二、 地点:玉泉校区永谦活动中心
  三、 活动内容:
  1. 15:00-15:20  浙江大学名誉教授受聘仪式
  2. 15:20-16:20  �岛教授作专题学术报告,题目为:Characterization and Applications of Nano-Carbon Materials
  3. 16:20–16:30 自由提问 
 
 
  欢迎有兴趣的师生参加!
 
 
浙江大学理学部和航空航天学院
2010年10月4日
 
 
报告摘要:
 

Characterization and Applications of Nano-Carbon Materials

S. Iijima
Faculty of Science and Technology, Meijo University,
National Institute of Advanced Industrial Science and Technology /Nanotube Research Center, Nagoya University and NEC
 
Firstly, the state of the art of synthesis of various nano-carbon materials that we have studied so far will be reviewed with the emphasis on the key points of the synthesis. One of challenge in the formation of SWCNT is to control its diameter and chirality, for which we tried to grow SWCNTs using metal catalyst of uni-sized metal clusters. The usual size of carbon nanohorn (CNH) aggregates is about 80 nm in diameter but its smaller size of less than 30nm is needed for a bio-medical application purpose (drug carrier for drug delivery system ) because of their higher permeation through biological cell membranes [1]. The small CNHs have been successfully realized by optimizing parameters for the growth of CNHs in CO2 laser ablation method of a carbon rod. The success is attributed to understanding of the condensation of carbon vapor in the CO2 laser ablation. Formation of a large size graphene sheet by thermal CVD method using a copper substrate foil has been reported [2]. The method requires a high temperature CVD reactor (near 1000℃), so that it cannot be used in a conventional Si device process and therefore an alternative low temperature synthesis of graphene is needed. For this purpose we developed a new micro-wave CVD method which has been developed originally for the nano-diamond film growth at low temperature down to room temperature [3]. We shall demonstrate the growth of an A4-size graphene sheet at 300℃.
In the last half part of the presentation will be concerned with structural characterization of nano-carbon materials using atom-resolution electron microscopes as well as other characterization methods of Raman, photoluminescence and optical absorption spectroscopy, etc The advantage of high resolution electron microscopy (HRTEM) over other techniques is to be able to characterize local atomic structures such as lattice defects and edge structures of nano materials which cannot be studied in conventional techniques. Another emphasis of HRTEM will be on dynamic observation of a reaction process which is not available for other high resolution probe microscope techniques such as STM. In terms of application of nano-carbon materials SWCNTs should be mentioned as an excellent TEM specimen support material. The SWCNTs were found to protect specimens from the electron beam irradiation damage when enclosed inside the central hollows of SWCNTs. Some examples of above mentioned observations will be demonstrated: latest results on structural characterization of carbon nanotubes [4-9], graphene [10], and boron nitride thin films [11], including “monatomic carbon strings that have been successfully made and observed in our laboratory [12].
 
1)            M. Zhang, et al. PNAS, 105, 14773(2008).
2)            S. Bae, et al. Nature Nanotech., (2010).
3)            M. Hasegawa et al., PRB, (2010).
4)            K. Suenaga, et al. Nature Nanotech. 2, 358 (2007)
5)            Z. Liu, et al., Nature Nanotech., 2, 422 (2007).
6)            Y. Sato, et al., Nano Lett, 7, 3704 (2007).
7)            C. H. Jin, et al., Nature Nanotech. 3, 17 (2008).
8)            C. H. Jin, et al., PRL, 101, 176102(1)-(4) (2008).
9)            M. Koshino, et al., Nature Chemistry (2010).
10)            Z. Liu, et al., PRL, 102, 015501 (1)-(4) (2009). 
11)            C. H. Jin, et al., PRL, 102, 195505 (1)-(4) (2009). 
12)            C. H. Jin, et al., PRL, 102, 205501 (1)-(4) (2009).

Iijima教授简介:
 
Professor Sumio Iijima is the discoverer of carbon nanotubes. Iijima's 1991 paper generated unprecedented interest in the carbon nanostructures and has since fueled intense research in the area of nanotechnology. For this and other work, Sumio Iijima was awarded, together with Louis Brus, the inaugural Kavli Prize for Nanoscience in 2008.

Professional Record
  • 1968-1974: Research Associate, Research Institute for Scientific Measurements, Tohoku University
  • 1970-1982: Senior Research Associate, Department of Physics, Arizona State University, Tempe, Arizona
  • (1979): Visiting Senior Scientist, Department of Metallurgy and Materials Science, University of Cambridge, Cambridge
  • 1982-1987: Group Leader, ERATO Program, Research Development Corporation of Japan, Nagoya
  • 1987-present: Senior Research Fellow, NEC Corporation, Tsukuba (Joined NEC in 1987 as Senior Principal Researcher)
  • 1998-2002: Research Director, JST/ICORP "Nanotubulites" Project Tsukuba and Nagoya
  • 1998-present: Professor, Meijo University, Nagoya (Visiting Lecturer, 1998 - 1999)
  • 2001-present: Director, Nanotube Research Center, National Institute of Advanced Industrial Science and Technology, Tsukuba
  • 2007-present: Special Adjunct Professor, Nagoya University
Honors, Awards
  • 1976: Bertram Eugene Warren Diffraction Physics Award, The American Crystallography Society, (The American Crystallography Society)
  • 1985: The Crystallographic Society of Japan Award, (The Crystallographic Society of Japan)
  • 1986: Minister Award, (The Agency of Science and Technology, Japan)
  • 1986: Best Paper Award, (The Japan Society for Applied Physics)
  • 1999: Tsukuba Prize, (The Science and Technology Promotion Foundation of Ibaraki, Japan)
  • 2002: J.C.McGroddy Prize for New Materials, (American Physical Society)
  • 2002: Agilent Europhysics Prize, (European Physical Society)
  • 2002: Benjamin Franklin Medal in Physics, (The Franklin Institute)
  • 2002: Honorary Doctor of the University of Antwerp
  • 2002: Chunichi Bunka Award, (Chunichi Shinbun Co., Ltd., Japan)
  • 2002: Japan Academy Award and Imperial Award, (The Japan Academy)
  • 2003: The JSAP Outstanding Achievement Award, (The Japan Society of Applied Physics)
  • 2003: Honorary Doctor of Ecole Polytechnique Federale de Lausanne (EPFL)
  • 2003: Person of Cultural Merits, (Japanese Government)
  • 2004: Society’s Medal of Achievement in Carbon Science and Technology, (The American Carbon Society)
  • 2005: Distinguished Scientist Award, Physical Sciences, (Microscopy Society of America)
  • 2005: Honorary Professor of Peking University
  • 2006: The John M. Cowley Medal 2006, (The International Federation of Societies for Microscopy)
  • 2007: Gregori Aminoff Prize in crystallography 2007, (Royal Swedish Academy of Sciences)
  • 2007: Foreign Associate, (National Academy of Sciences)
  • 2008: The 2008 Plueddemann Award, (Case Western University)
  • 2008: The First Richard E. Smalley Research Award, (The Electrochemical Society)
  • 2008: The Prince of Asturias Award for Technical Scientific Research 2008, (The Prince of Asturias Foundation, Spain)
  • 2008: Economist Innovation Awards “No Boundaries” (The Economist, UK)
  • 2008: George Pimentel Lecturer (U.C. Berkeley, USA)
  • 2009: Foreign Member of The Norwegian Academy of Science and Letters
  • 2009: Honorary Professor of Tsinghua University
  • 2009: Order of Cultural Merits (Japanese Government)
Societies
  • National Academy of Sciences, Foreign Associates
  • The Norwegian Academy of Science and Letters, Foreign Member
  • Royal Microscopy Society, Honorary Fellowship
  • The American Physical Society, Fellow
  • Nanostructured materials, Associate Editor
  • Ultramicroscopy, Advisory Editorial Board
  • Journal Nano, Editorial Board
  • Journal of electron microscopy, Advisory Board
  • Journal of Applied Physics, Advisory Board
  • Science Council of Japan
  • Microscopy Society of Japan
 
 
 
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