《碳納米管和石墨烯(英文版)》是2015年科學出版社出版的圖書,作者是趙廷凱,李鐵虎,柳永寧。
基本介紹
- 書名:碳納米管和石墨烯(英文版)
- 作者:趙廷凱、李鐵虎、柳永寧
- ISBN:978-7-03-040052-9
- 定價:108.00
- 出版社:科學出版社
- 出版時間:2015年6月
- 裝幀:精裝
- 開本:B5
- 版本:101
- 責任編輯:李萍、甄文全
- 字數:340千字
- 編輯部:西安分公司
內容簡介,作者簡介,目錄,
內容簡介
本書目錄專家評論讀者評論我要留言
新型碳納米材料是納米材料領域研究的熱點問題,近十幾年來突飛猛進。石墨烯自從2010年獲得諾貝爾獎後,更是異軍突起,備受關注,也使人們對碳納米材料的研究更加熱衷,並取得了豐碩的成果。本書較為系統地總結和歸納了作者的相關研究成果,介紹了新型碳納米材料,尤其是碳納米管、石墨烯等的製備工藝、生長機理、相關特性以及實際套用等。
本書以全英文出版,向國內的高年級本科生、研究生、留學生以及相關科技工作者提供最新的碳納米管和石墨烯研究成果,以期成為新型碳納米材料──碳納米管和石墨烯比較全面系統的技術參考資料。
作者簡介
Dr. Zhao Tingkai is a professor of materials science and engineering at Northwestern Polytechnical University (NPU) in Xi'an, China.He received his PhD degree from Xi'an Jiaotong University (XJTU,China) in 2005 and studied as a postdoctoral research fellow at XJTU from 2005 to 2007, and visited Northwestern University (Evanston, USA) and University of Oxford (Oxford, UK) as visiting scholar. His research group mainly investigates the synthesis, structure and performance of advanced carbon materials such as carbon nanotubes (especially amorphous carbon nanotubes), graphene, carbon foam as well as pitch modification, and their applications on solar cell, lithium ion battery, electrochemical devices and military fields. He has also contributed to the area of non-ferrous metals hydrometallurgy.
目錄
Foreword
Preface
Acknowledgements
Chapter i Carbonnanomaterials
1.1 Fundamental concepts of nanomaterials and carbon
1.1.1 Nanometer
1.1.2 Definition of nanomaterials
1.1.3 The history of carbon
1.2 Allotropes of carbon
1.2.1 Diamond
1.2.2 Graphite
1.2.3 Lonsdaleite
1.2.4 Buckminsterfullerene
1.2.5 Amorphous carbon
1.2.6 Carbon nanotubes
1.2.7 Glassy carbon
1.2.8 Carbon nanofoam
1.2.9 Carbon nanobud
1.2.10 Graphene
1.2.11 Other possible carbon forms
1.3 The development of carbon nanomaterials
1.4 The classification of carbon nanomaterials
References
Chapter 2 Synthesis of carbon nanotubes
2.1 The history and discovery of CNTs
2.1.1 History of CNTs
2.1.2 Discovery of CNTs
2.2 The classification of CNTs
2.3 The structure and properties of CNTs
2.3.1 Structure
2.3.2 Properties
2.4 Overview of CNT synthesis methods
2.4.1 AD method
2.4.2 LA method
2.4.3 CVD method
2.4.4 Ball milling
2.4.5 Natural,incidental and controlled flame environments
2.4.6 Other methods
2.5 Temperature—controlled arc discharge(TC—AD)method
2.5.1 Preparation of SWCNTs by TC—AD
2.5.2 Preparation of ACNTs by TC—AD
2.5.3 Preparation of other forms carbon nanomaterials
2.6 Growth mechanism of carbon nanotube
2.6.1 Mechanism of crystalline CNT formation
2.6.2 Mechanism of ACNTs formation
References
Chapter 3 Purification and separation of CNTs
3.1 Overview of CNT purification methods
3.1.1 Chemical oxidation
3.1.2 Physical purification
3.1.3 Physical and chemical combination purification
3.2 Two—step purification method of SWCNTs
3.2.1 Effect factors of SWCNT purification
3.2.2 Characterization
3.3 Overview of SWCNT separation
3.3.1 In situ separation of m—or s—SWCNTs
3.3.2 Post—treatment methods
3.3.3 Characterization of SWCNTs
3.4 DGU separation of SWCNTs
3.4.1 Effect of the separation temperature
3.4.2 Effect of the surfactant types
3.4.3 Effects of SDS concentration on separation
3.4.4 Effect of agarose concentration on the DGU separation
References
Chapter 4 The applications of carbon nanotubes
4.1 Overview of CNT applications
4.2 Functionalized CNTs
4.2.1 Functionalization and dispersion of CNTs
4.2.2 Preparation of the functionalized—CNT composites
4.3 Applications of carbon nanotubes in energy conversion
4.3.1 Hydrogen storage
4.3.2 Lithium ion secondary batteries
4.4 Application of CNTs in military
4.4.1 Electromagnetic wave absorber
4.4.2 Electromagnetic shielding structure
4.5 Application of CNTs in electrochemistry
4.5.1 MWCNT/CMC and electrochemical performance
4.5.2 MWCNT/CS and electrochemical performance
4.5.3 MWCNT/FeaO4 and electrochemical performance
4.5.4 MWCNT/HAP and electrochemical performance
References
Chapter 5 Graphene
5.1 History and discovery of graphene
5.2 Mother of all graphitic forms
5.2.1 What's graphene?
5.2.2 Description of graphene
5.3 Structure and properties of graphene
5.3.1 Atomic structure
5.3.2 Properties
5.4 The synthesis methods of graphene
5.5 Graphene growth with great size by CVD
5.5.1 The transfer of graphene from copper foil to quartz slide
5.5.2 The effects of reaction time on graphene
5.5.3 The effects of reaction temperature on graphene
5.5.4 The effects of gas flow in the quartz tube on graphene
5.5.5 The electrocatalytic properties of graphene
5.6 Potential applications of graphene
5.7 The future of graphene
References
Preface
Acknowledgements
Chapter i Carbonnanomaterials
1.1 Fundamental concepts of nanomaterials and carbon
1.1.1 Nanometer
1.1.2 Definition of nanomaterials
1.1.3 The history of carbon
1.2 Allotropes of carbon
1.2.1 Diamond
1.2.2 Graphite
1.2.3 Lonsdaleite
1.2.4 Buckminsterfullerene
1.2.5 Amorphous carbon
1.2.6 Carbon nanotubes
1.2.7 Glassy carbon
1.2.8 Carbon nanofoam
1.2.9 Carbon nanobud
1.2.10 Graphene
1.2.11 Other possible carbon forms
1.3 The development of carbon nanomaterials
1.4 The classification of carbon nanomaterials
References
Chapter 2 Synthesis of carbon nanotubes
2.1 The history and discovery of CNTs
2.1.1 History of CNTs
2.1.2 Discovery of CNTs
2.2 The classification of CNTs
2.3 The structure and properties of CNTs
2.3.1 Structure
2.3.2 Properties
2.4 Overview of CNT synthesis methods
2.4.1 AD method
2.4.2 LA method
2.4.3 CVD method
2.4.4 Ball milling
2.4.5 Natural,incidental and controlled flame environments
2.4.6 Other methods
2.5 Temperature—controlled arc discharge(TC—AD)method
2.5.1 Preparation of SWCNTs by TC—AD
2.5.2 Preparation of ACNTs by TC—AD
2.5.3 Preparation of other forms carbon nanomaterials
2.6 Growth mechanism of carbon nanotube
2.6.1 Mechanism of crystalline CNT formation
2.6.2 Mechanism of ACNTs formation
References
Chapter 3 Purification and separation of CNTs
3.1 Overview of CNT purification methods
3.1.1 Chemical oxidation
3.1.2 Physical purification
3.1.3 Physical and chemical combination purification
3.2 Two—step purification method of SWCNTs
3.2.1 Effect factors of SWCNT purification
3.2.2 Characterization
3.3 Overview of SWCNT separation
3.3.1 In situ separation of m—or s—SWCNTs
3.3.2 Post—treatment methods
3.3.3 Characterization of SWCNTs
3.4 DGU separation of SWCNTs
3.4.1 Effect of the separation temperature
3.4.2 Effect of the surfactant types
3.4.3 Effects of SDS concentration on separation
3.4.4 Effect of agarose concentration on the DGU separation
References
Chapter 4 The applications of carbon nanotubes
4.1 Overview of CNT applications
4.2 Functionalized CNTs
4.2.1 Functionalization and dispersion of CNTs
4.2.2 Preparation of the functionalized—CNT composites
4.3 Applications of carbon nanotubes in energy conversion
4.3.1 Hydrogen storage
4.3.2 Lithium ion secondary batteries
4.4 Application of CNTs in military
4.4.1 Electromagnetic wave absorber
4.4.2 Electromagnetic shielding structure
4.5 Application of CNTs in electrochemistry
4.5.1 MWCNT/CMC and electrochemical performance
4.5.2 MWCNT/CS and electrochemical performance
4.5.3 MWCNT/FeaO4 and electrochemical performance
4.5.4 MWCNT/HAP and electrochemical performance
References
Chapter 5 Graphene
5.1 History and discovery of graphene
5.2 Mother of all graphitic forms
5.2.1 What's graphene?
5.2.2 Description of graphene
5.3 Structure and properties of graphene
5.3.1 Atomic structure
5.3.2 Properties
5.4 The synthesis methods of graphene
5.5 Graphene growth with great size by CVD
5.5.1 The transfer of graphene from copper foil to quartz slide
5.5.2 The effects of reaction time on graphene
5.5.3 The effects of reaction temperature on graphene
5.5.4 The effects of gas flow in the quartz tube on graphene
5.5.5 The electrocatalytic properties of graphene
5.6 Potential applications of graphene
5.7 The future of graphene
References
