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Handbook of Carbon Nano Materials Volumes 5-6 : Volume 5: Graphene - Fundamental Properties Volume 6: Graphene - Energy and Sensor Applications /
The fifth and sixth volumes of the Handbook of Carbon Nano Materials focus on fundamental properties and key applications of graphene. Graphene, the thinnest known material made of a single atom thick sheet of carbon atoms arranged hexagonally, offers great opportunities for application development...
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Singapore :
World Scientific Publishing Company,
[2014]
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| Colección: | Handbook of carbon nano materials ;
v. 5-6. World Scientific series on carbon nanoscience. |
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Volumes 5 and 6; Chapter 1 Fundamental Properties of Graphene; 1. Introduction; 2. Electronic Properties of Pristine Graphene; 2.1. Band structure; 2.1.1. Few-layered graphene; 2.2. Chirality and quantum hall effect; 2.3. The Klein tunneling in graphene; 2.4. Atomic collapse on graphene; 3. Elastic Properties of Graphene; 4. Structural Defects in Graphene; 4.1. Stone-Wales defects; 4.2. Carbon vacancies; 4.3. Carbon adatoms; 4.4. Grain boundary loops; 4.5. Noncarbon adatoms and substitutional impurities; 4.6. Grain boundaries.
- 4.7. Effect of defects on the properties of graphene5. Summary; Acknowledgments; References; Chapter 2 Adsorption on and Reactivity of Carbon Nanotubes and Graphene; 1. Introduction; 2. Structure and Adsorption Sites; 2.1. Structure and adsorption sites of graphene and FLG; 2.1.1. Presence of defects; 2.2. Structure and adsorption sites of carbon nanotubes; 2.2.1. Presence of defects; 3. Physisorption on CNTs and Graphene; 3.1. Physisorption of gases on CNTs and graphene; 3.1.1. Physisorption on individual CNTs; 3.1.2. Physisorption on CNT bundles; 3.1.3. Physisorption on graphene.
- 3.2. Physisorption of liquids on CNTs and graphene3.2.1. Adsorption of water on CNTs and graphene; 3.2.2. Physisorption of ionic liquids on graphene and CNTs; 3.2.3. Physisorption on CNTs and graphene of ions and molecules from solution; 3.2.4. Physisorption of liquids on doped CNTs and graphene; 3.3. Physisorption of solids on CNTs and graphene; 3.3.1. Metals and semiconductors; 3.3.2. Physisorption of metals and semiconductors on doped CNTs or graphene; 3.3.3. Physisorption of polymers; 3.3.4. Polymer adsorption on doped graphene or CNTs; 4. Chemisorption on CNTs and Graphene.
- 4.1. Chemisorption of gases on CNTs and graphene4.1.1. Gas chemisorption on CNTs; 4.1.2. Effect of dopants on gas chemisorption with CNTs; 4.1.3. Gas chemisorption on graphene; 4.1.4. Effect of dopants on gas chemisorption with graphene; 4.2. Chemisorption of liquids on CNTs and graphene; 4.3. Chemisorption of solids on CNTs and graphene; 4.3.1. Alkali metals; 4.3.2. Alkaline-earth metals; 4.3.3. d-metals; 4.3.4. Adsorption of other metals, metalloids, and non-metals; 4.3.5. Polymers; 5. Reactivity on CNTs and Graphene; 5.1. Surface chemistry of nanostructured carbon materials; 5.2. Catalysis.
- 5.2.1. CNTs, CNFs, and FLG as metal-free catalyst5.2.2. Hydrogenation; 5.2.3. Oxidation and environmental catalysis; 5.2.4. Fuel cell catalysis; 5.3. Gas sensors; 5.4. Bioreactivity and degradability of CNTs and graphene; 5.4.1. Biosensors; 5.4.2. Drug delivery; 5.4.3. Biodegradability and toxicity; References; Chapter 3 Chemical Manipulation of Graphene in Dispersions; 1. Introduction; 2. Liquid-Phase Exfoliated Graphene; 2.1. Ultrasonication of graphite; 2.1.1. Graphene dispersions in organic solvents; 2.1.2. Graphene dispersions in surfactant solutions; 2.2. Non-ultrasonication techniques.