2002/02/01 p.1 奈米碳管的性質與應用 Dr. Rational You IEK/ITRI 2002/02/01 Source:

Slides:

Advertisements

Similar presentations

Nanotechnology. Research and technology development at the atomic, molecular or macromolecular levels, in the length scale of approximately nanometer.

Advertisements

Simulations of Nanomaterials: Carbon Nanotubes, Graphene and Gold Nanoclusters Iván Cabria, María J. López, Luis M. Molina, Nicolás A. Cordero, P. A. Marcos,

PA4311 Quantum Theory of Solids Quantum Theory of Solids Mervyn Roy (S6) www2.le.ac.uk/departments/physics/people/mervynroy.

1 Chi-cheng Chiu The University of Texas at Dallas 12/11/2009 Computer Simulations of the Interaction between Carbon Based Nanoparticles and Biological.

Section 4 Molecular crystal Discovery and Applications of fullerenes.

8-1: Properties of Carbon

Atmospheric Chemistry, Environmental Science and Nanoscience The Real Life Science Guest Speaker Series Monday, March 12th 2:35 – 3:10 Room 305 Prof. Robert.

F.6 Chemistry Internet Searching Activity 2 Discovery and Application of Fullerenes By Chor Tak Lam (1) F.6B.

Bottom-up Technology Toshitake Takahashi. Background on the synthesis of graphene sheet and graphene nanoribbon W. A. de Heer, et. al. Science 2006, 312,

高分子材料實驗室程耀毅博士學歷：美國麻省理工學院經歷：台灣積體電路公司薄膜研究副理現任：分子系高分子所副教授

Master of Philosophy Materials Modelling

Chapter 1 序論 Introduction. 2/15 Contents 1.1. 工程分析 Engineering Analysis 1.2. 教學目標與方法 Objectives and Approaches.

Master of Philosophy Materials Modelling

Carbon Nanotube Memory Yong Tang 04/26/2005 EE 666 Advanced Solid State Device.

6. Carbon nanostructures: fullerenes and carbon nanotubes 1.

Conjugated Polymers and Carbon Nanotubes for Optoelectronic Applications Liming Dai Department of Polymer Engineering College of Polymer Science and Polymer.

Chemistry and Nanomaterials Carl C. Wamser Portland State University Nanomaterials Course - June 27, 2006 Carl C. Wamser Portland State University Nanomaterials.

Compressive behavior and buckling response of carbon nanotubes (CNTs) Aswath Narayanan R Dianyun Zhang.

09 生醫奈米粒子同材料奈米尺寸的粒子與較大尺寸的粒子，其光學等物理性質相異. Gold nanoparticles The Lycurgus Cup dates from Roman times. The glass appears green in daylight (reflected light),

A Career in Physics and Astronomy Steven R. Spangler University of Iowa.

Gaxela N, Manaetja K.P, Mulaudzi S, Senosi R Supervisor: Dr V.L.Katkof.

Carbon Nanotubes Deanna Zhang Chuan-Lan Lin May 12, 2003.

An Intoduction to Carbon Nanotubes

Nanomaterials - carbon fullerenes and nanotubes Lecture 3 郭修伯.

Carbon Nanotubes Matthew Smith. Contents What they are Who developed them How they are synthesised What their properties are What they are used for.

Temperature Effects on the Electronic Conductivity of Carbon Nanotubes Mark Mascaro Department of Materials Science and Engineering Advisor Francesco Stellacci.

Carbon Nano-tubes: An Overview An Undergraduate Research Paper By Scott E. Wadley for the Department of Aerospace Engineering at The University of Kansas.

NANOTUBES By Jacqueline Barton Material Science 3344 Dr. Larry Peel February 25, 2005.

Unit 3 Nanomaterials.

ECE : Nanoelectronics Prof. Virginia Ayres Electrical & Computer Engineering Michigan State University

Surface nano-patterning has been intensively investigated for wide applications in different nano-devices. Existing surface patterning techniques have.

An Introduction to Carbon Nanotubes

Epitaxial graphene Claire Berger GATECH- School of Physics, Atlanta CNRS-Institut Néel, Grenoble NIRT Nanopatterned Epitaxial graphite.

Molecular Nanostuctures 1. Introduction. Carbon hybridization and allotropes Alexey A. Popov, IFW Dresden

Johnson Space Center May 18, Single-walled Carbon Nanotube (SWCNT) Carbon Nanostructures C 60 (Buckminsterfullerene)

Nano physics (Phys 4190) Dr. Abeer Kamal Abd El-Aziz

Allotropes nanotube of carbon. Allotropes of Carbon GraphiteBuckminsterfullereneDiamond Zumdahl, Zumdahl, DeCoste, World of Chemistry  2002, page 27.

The Basics of Carbon Nanotube Displays Group 9 Jeffrey Cook and Derrick Williams.

Electron Transport in Carbon Nanotubes

4/22/2002, Monday Homework Comments: Scientists and Their Works.

Nano-Technology Lee Zi Jing 3i3 (13).

NH 3 Orion RA Chiu ea 1967 HC 5 N synth Alexander ea HC 7 N in TMC1 HC 7 N Red Giant Star C 60 Kroto et al C 28 Kroto C 60 Ph 5 Cl Taylor ac1976 C 240.

ME 381R Fall 2003 Micro-Nano Scale Thermal-Fluid Science and Technology Lecture 11: Thermal Property Measurement Techniques For Thin Films and Nanostructures.

Peng He, Donglu Shi, Wim J. van Ooij

Carbon Nanotubes Riichiro Saito

Graphene as a new page in Solid State Physics L.A. Falkovsky Landau Institute for Theoretical Physics Institute of High Pressure Physics.

The original aim was to understand molecular vibrational dynamics In a carbon plasma simulating a stellar atmosphere we discovered C 60 Thus a totally.

DIBs McKellar1936 C 33 Hinten- berger ea l1960 Supersonic Nozzle Smalley Levy Wharton NH 3 Orion RA Chiu ea 1967 C 3 comets Douglas 1936 RC 32 R Walton.

Nanotubes By: Mariela Rodriguez. Nanotubes Definition: A flat layer of graphite rolled into a tube. Physicist Alex Zettl, shown here with a model of a.

Molecular Simulations of Nano- and Bio-Materials Venkat Ganesan Computations Fluid Mechanics Biology Statistical Mechanics Venkat Ganesan: CPE 3.414,

Science 10.  Non-metal atoms sharing electrons  Can form two structures:  Simple molecular structure (last class) ◦ Simple, small molecules ◦ Strong.

Special Focus: Carbon Nanostructures

Dr Martyn A. McLachlan Department of Materials Imperial College London

Molybdenum Sulphide Nanostructures (pioneered by Reshef Tenne and co-workers)

Namas Chandra and Sirish Namilae

Temperature Effects on the Electronic Conductivity of Carbon Nanotubes Mark Mascaro Department of Materials Science and Engineering Advisor Francesco Stellacci.

NANO TECHNOLOGY Bhimavaram Institute of Engineering &Technology

International Conference on Sustainable Built Environment

Department of Chemistry University of Hong Kong

Dennis K. P. Ng Department of Chemistry Curriculum Leadership Program

Pure Ni Raman spectroscopy wear map CNT-Ni Raman spectroscopy wear map

Andre Taylor and Jan Schroers, Yale University

Table 11. Chi-Square Analysis Based on Grade Shift for Study Group

Engineering Materials 23

Dr. Rational You IEK/ITRI 2002/02/01

Electromechanical response

Chemistry and Nanomaterials

Organic Photovoltaics: Focus on Its Strengths

Presentation transcript:

2002/02/01 p.1 奈米碳管的性質與應用 Dr. Rational You IEK/ITRI 2002/02/01 Source: (2001/11)

2002/02/01 p.2 Outline Source: (2001/11)

2002/02/01 p.3 碳的同素異形結構 Source: (2001/11)

2002/02/01 p.4 奈米碳管之物理性質 Source: (2001/11)

2002/02/01 p.5 Reference 1. W. Kratschmer, Lowell D. Lamb, K. Fostiropoulos and R. Donald Huffman, "Solid C60 : a new form of carbon", Nature, 347, (1990). 2. S. Iijima, "Helical microtubules of graphite carbon", Nature, 354, (1991). 3. Rice University: Rick Smalley's Group Home Page--Image Gallery. 4. G. Collins and P. Avouris, "Nanotubes for electronics", Scientific American, December, (2000). 5. S. Xei, W. Li, Z. Pan, B. Chang and L. Sun, "Mechanical and physical properties on carbon nanotube", Journal of Physics and Chemistry of Solid, 61, (2000). 6. J. Han and Al Globus, "Molecular Dynamics Simulations of Carbon Nanotube Based Gears", in MGMS/ECI/simulation/paper. 7. Bonard Jean-Marc, Salvetat Jean-Paul, Thomas Stockli, A. De Heer Walt, Laszlo Forro and Andre Chatelain, "Fieid emission from single-wall carbon nanotube films", Applied Physics Letters, 73, (1998). 8. B. I. Yakobson and R. E. Smalley, "Fullerene Nanotubes : C and Beyond", American Scientist, 85, ( ) J. Cumings and A. Zettl, "Low-Friction Nanocale Linear Bearing Realized from Multiwall Carbon Nanotubes", Science, 289, ( ) M. R. Falvo, G. J. Clary, R. M. Taylor, V. Chi, F. P. Jr. Brooks, S. Washburn and R. Superfine, "Bending and buckling of carbon nanotubes under large strain", Nature, 389, (1997). 11. M. Nardelli, B. I. Yakobson, and J. Bernhole "Brittle and ductile behavior in carbon nanotube", Physical Review Letters, 81, (1998). 12. H. Ray Bauyhman et al, "Carbon Nanotube Actuators", Science, 284, ( ) S. Iijima, M. Yudasaka, R. Yamada, S. Bandow, K. Suenaga, F. Kokai and K. Takahashi "Nano-aggregates of single-walled graphite carbon nano-horns" Chemical Physics Letters, 309, (1999). 14. G. A. J. Amaratunga, "Field Emission from Nanostructured Carbon", International School of Solid State Physics- 18th course : Nanostructured Carbon for Advanced Applications (NATO-ASI), 2000, Italy. 15. R. Saito, G. Dresselhaus and M. S. Dresselhaus, Physical Properties of carbon nanotubes, Imperial College Press, P. 78. Source: (2001/11)