Amsterdam ; ; Oxford, : Elsevier, 2006

1-280-64162-2

9786610641628

0-08-045932-3

1 online resource (751 p.)

DaiLiming <1961->

620.193

620.5

Carbon

Nanostructured materials

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Front cover; Title page; Copyright page; Table of contents; Foreword; Preface; Acknowledgments; List of Contributors; Introduction; 1 From conventional technology to carbon nanotechnology: The fourth industrial revolution and the discoveries of C60, carbon nanotube and nanodiamond; 1. THE INDUSTRIAL REVOLUTIONS THAT CHANGED THE WORLD; 2. NANOTECHNOLOGY-THE FOURTH INDUSTRIAL REVOLUTION; 2.1. The bottom up vs. top down approaches; 2.2. The size and surface effects; 3. CARBON NANOTECHNOLOGY; 3.1. The discovery of fullerene C60; 3.2. The discovery of carbon nanotube

3.3. The discovery of nanodiamondREFERENCES; Part I Synthesis and Structure of Carbon Nanomaterials; 2 Synthesis, growth mechanism and processing of carbon nanotubes; 1. INTRODUCTION; 2. SYNTHETIC STRATEGIES; 2.1. Multi-walled carbon nanotubes; 2.1.1. Chemical vapor deposition; 2.1.2. Plasma-enhanced chemical vapor deposition; 2.1.3. Vapor-phase growth; 2.2. Single-walled carbon nanotubes; 2.2.1. Optical plasma control; 2.2.2. Catalyst composition; 2.2.3. Improvement of oxidation resistance; 2.2.4. Laser vaporization; 2.2.5. Pyrolysis or vapor-phase deposition

2.2.6. Chemical vapor deposition2.2.7. Alcohol catalytic chemical vapor

deposition; 2.2.8. Laser-assisted thermal chemical vapor deposition; 2.2.9. High-pressure CO disproportionation process; 2.2.10. Flame synthesis; 2.3. Peapods; 2.4. Double-walled carbon nanotubes; 3. MECHANISM OF GROWTH; 4. PURIFICATION AND SEPARATION OF CARBON NANOTUBES AND RELATED ASPECTS; 4.1. Purification and separation of carbon nanotubes; REFERENCES; 3 Solid-state formation of carbon nanotubes; 1. INTRODUCTION OF A BALL MILLING-ANNEALING METHOD; 2. HIGH-ENERGY BALL MILLING; 3. HIGH ENERGY BALL MILLING OF GRAPHITE

3.1. Microporous structures3.2. Phase transformations; 3.3. Metal particle inclusion; 4. SOLID-STATE FORMATION PROCESS OF CNTS; 4.1. Single-walled nanotubes; 4.2. Multi-walled nanotubes; 4.3. Bamboo-type nanotubes; 4.4. Nanoporous particles; 5. FORMATION MECHANISMS; 5.1. Nucleation structures; 5.2. Solid-state growth process; 6. SUMMARY; Acknowledgments; REFERENCES; 4 Catalytic chemical vapor deposition of single-walled carbon nanotubes; 1. INTRODUCTION/BACKGROUND; 1.1. Structure of SWNT; 1.2. Properties of SWNTs; 1.3. Synthesis of SWNTs; 2. CHEMICAL VAPOR DEPOSITION OF SWNT

2.1. Bulk growth of SWNTs2.1.1. Growth on supported catalyst; 2.1.2. Growth on floating catalyst; 2.2. Surface growth of SWNT; 2.2.1. Catalyst preparation; 2.2.2. Carbon precursors; 2.2.3. Substrate; 3. DISCUSSIONS; 3.1. Diameter control; 3.2. Length control; 3.3. Orientation control; 4. SUMMARIES AND OUTLOOKS; REFERENCES; 5 Fabrication of fullerene nanostructures; 1. INTRODUCTION; 2. THE FORMATION OF HIGHLY-ORDERED C60 AND C70 ADLAYERS ON SINGLE-CRYSTAL SURFACES; 3. ADLAYERS OF CALIXARENE AND CALIXARENE/FULLERENE COMPLEX; 3.1. The structure of highly ordered OBOCMC8 adlayer

3.2. The structure of highly ordered C60/OBOCMC8 adlayer

Nanotechnology is no longer a merely social talking point and is beginning to affect the lives of everyone. Carbon nanotechnology as a major shaper of new nanotechnologies has evolved into a truly interdisciplinary field, which encompasses chemistry, physics, biology, medicine, materials science and engineering. This is a field in which a huge amount of literature has been generated within recent years, and the number of publications is still increasing every year. Carbon Nanotechnology aims to provide a timely coverage of the recent development in the field with updated reviews and remarks by