Enhanced Carbon-Based Materials and Their Applications
portes grátis
Enhanced Carbon-Based Materials and Their Applications
Xie, Mengying; Dee, Chang Fu; Ooi, Poh Choon
Wiley-VCH Verlag GmbH
12/2022
256
Dura
Inglês
9783527348022
15 a 20 dias
Descrição não disponível.
CHAPTER 1: INTRODUCTION
CHAPTER 2: CARBON BASED NANOSTRUCTURES
2.1 Introduction
2.2 Synthesis of carbon-based nanostructures
2.3 Characterization techniques
2.4. Summary
CHAPTER 3: FUNCTIONAL CARBON-BASED MATERIALS and APPLICATIONS
3.1 Introduction and background of carbon-based sensors
3.2 Carbon material functionalization, hybridization and sensing properties
3.3 Plasma surface modification of graphene
3.4 Electronic and chemical properties of functionalized graphene
3.5 Applications
CHAPTER 4: RESISTIVE SWITCHING CARBON-BASED MEMORIES
4.1 Introduction
4.2 Fabrication method
4.3 Electrical characterization and applications
CHAPTER 5: CARBON-BASED OPTOELECTRONIC DEVICES
5.1 Emerging carbon-based device concept
5.2 0, 1, and 2- Dimensional carbon-based materials in optoelectronic applications
CHAPTER 6: THERMOELECTRIC ENERGY HARVESTERS and APPLICATIONS
6.1 Carbon enhanced materials overview
6.2 Thermoelectric energy harvester overview
6.3 Fabrication
6.4 Applications
CHAPTER 7: PIEZOELECTRIC ENERGY HARVESTERS and APPLICATIONS
7.1. Introduction of piezoelectric energy harvester
7.2. Fabrication
7.3. Applications
CHAPTER 8: ACTUATORS BASED on the CARBON ENHANCED MATERIALS
8.1 Introduction
8.2 Nanostructured Carbon: Effective Tools for Carbon-Based Nanoactuators
8.3 Applications (Carbon Nanotube-Based Actuators, Graphene and Graphene Oxide Actuators, Fullerene-Based Actuators)
8.4 Challenges and Prospective of Actuators
CHAPTER 9: CARBON-BASED ANALOG and DIGITAL ELECTRONICS and CIRCUITS
9.1 Current development on Analog and Digital Electronics
9.2 Radio frequency circuits
9.3 Carbon nanotubes and graphene digital electronics
CHAPTER 10: CONCLUSIONS and FUTURE PERSPECTIVES
CHAPTER 2: CARBON BASED NANOSTRUCTURES
2.1 Introduction
2.2 Synthesis of carbon-based nanostructures
2.3 Characterization techniques
2.4. Summary
CHAPTER 3: FUNCTIONAL CARBON-BASED MATERIALS and APPLICATIONS
3.1 Introduction and background of carbon-based sensors
3.2 Carbon material functionalization, hybridization and sensing properties
3.3 Plasma surface modification of graphene
3.4 Electronic and chemical properties of functionalized graphene
3.5 Applications
CHAPTER 4: RESISTIVE SWITCHING CARBON-BASED MEMORIES
4.1 Introduction
4.2 Fabrication method
4.3 Electrical characterization and applications
CHAPTER 5: CARBON-BASED OPTOELECTRONIC DEVICES
5.1 Emerging carbon-based device concept
5.2 0, 1, and 2- Dimensional carbon-based materials in optoelectronic applications
CHAPTER 6: THERMOELECTRIC ENERGY HARVESTERS and APPLICATIONS
6.1 Carbon enhanced materials overview
6.2 Thermoelectric energy harvester overview
6.3 Fabrication
6.4 Applications
CHAPTER 7: PIEZOELECTRIC ENERGY HARVESTERS and APPLICATIONS
7.1. Introduction of piezoelectric energy harvester
7.2. Fabrication
7.3. Applications
CHAPTER 8: ACTUATORS BASED on the CARBON ENHANCED MATERIALS
8.1 Introduction
8.2 Nanostructured Carbon: Effective Tools for Carbon-Based Nanoactuators
8.3 Applications (Carbon Nanotube-Based Actuators, Graphene and Graphene Oxide Actuators, Fullerene-Based Actuators)
8.4 Challenges and Prospective of Actuators
CHAPTER 9: CARBON-BASED ANALOG and DIGITAL ELECTRONICS and CIRCUITS
9.1 Current development on Analog and Digital Electronics
9.2 Radio frequency circuits
9.3 Carbon nanotubes and graphene digital electronics
CHAPTER 10: CONCLUSIONS and FUTURE PERSPECTIVES
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Carbon-based material synthesis; carbon-based material characterization; carbon-based material applications; carbon-based material overview; carbon-based material text; advanced carbon-based material applications; carbon-enhanced materials
CHAPTER 1: INTRODUCTION
CHAPTER 2: CARBON BASED NANOSTRUCTURES
2.1 Introduction
2.2 Synthesis of carbon-based nanostructures
2.3 Characterization techniques
2.4. Summary
CHAPTER 3: FUNCTIONAL CARBON-BASED MATERIALS and APPLICATIONS
3.1 Introduction and background of carbon-based sensors
3.2 Carbon material functionalization, hybridization and sensing properties
3.3 Plasma surface modification of graphene
3.4 Electronic and chemical properties of functionalized graphene
3.5 Applications
CHAPTER 4: RESISTIVE SWITCHING CARBON-BASED MEMORIES
4.1 Introduction
4.2 Fabrication method
4.3 Electrical characterization and applications
CHAPTER 5: CARBON-BASED OPTOELECTRONIC DEVICES
5.1 Emerging carbon-based device concept
5.2 0, 1, and 2- Dimensional carbon-based materials in optoelectronic applications
CHAPTER 6: THERMOELECTRIC ENERGY HARVESTERS and APPLICATIONS
6.1 Carbon enhanced materials overview
6.2 Thermoelectric energy harvester overview
6.3 Fabrication
6.4 Applications
CHAPTER 7: PIEZOELECTRIC ENERGY HARVESTERS and APPLICATIONS
7.1. Introduction of piezoelectric energy harvester
7.2. Fabrication
7.3. Applications
CHAPTER 8: ACTUATORS BASED on the CARBON ENHANCED MATERIALS
8.1 Introduction
8.2 Nanostructured Carbon: Effective Tools for Carbon-Based Nanoactuators
8.3 Applications (Carbon Nanotube-Based Actuators, Graphene and Graphene Oxide Actuators, Fullerene-Based Actuators)
8.4 Challenges and Prospective of Actuators
CHAPTER 9: CARBON-BASED ANALOG and DIGITAL ELECTRONICS and CIRCUITS
9.1 Current development on Analog and Digital Electronics
9.2 Radio frequency circuits
9.3 Carbon nanotubes and graphene digital electronics
CHAPTER 10: CONCLUSIONS and FUTURE PERSPECTIVES
CHAPTER 2: CARBON BASED NANOSTRUCTURES
2.1 Introduction
2.2 Synthesis of carbon-based nanostructures
2.3 Characterization techniques
2.4. Summary
CHAPTER 3: FUNCTIONAL CARBON-BASED MATERIALS and APPLICATIONS
3.1 Introduction and background of carbon-based sensors
3.2 Carbon material functionalization, hybridization and sensing properties
3.3 Plasma surface modification of graphene
3.4 Electronic and chemical properties of functionalized graphene
3.5 Applications
CHAPTER 4: RESISTIVE SWITCHING CARBON-BASED MEMORIES
4.1 Introduction
4.2 Fabrication method
4.3 Electrical characterization and applications
CHAPTER 5: CARBON-BASED OPTOELECTRONIC DEVICES
5.1 Emerging carbon-based device concept
5.2 0, 1, and 2- Dimensional carbon-based materials in optoelectronic applications
CHAPTER 6: THERMOELECTRIC ENERGY HARVESTERS and APPLICATIONS
6.1 Carbon enhanced materials overview
6.2 Thermoelectric energy harvester overview
6.3 Fabrication
6.4 Applications
CHAPTER 7: PIEZOELECTRIC ENERGY HARVESTERS and APPLICATIONS
7.1. Introduction of piezoelectric energy harvester
7.2. Fabrication
7.3. Applications
CHAPTER 8: ACTUATORS BASED on the CARBON ENHANCED MATERIALS
8.1 Introduction
8.2 Nanostructured Carbon: Effective Tools for Carbon-Based Nanoactuators
8.3 Applications (Carbon Nanotube-Based Actuators, Graphene and Graphene Oxide Actuators, Fullerene-Based Actuators)
8.4 Challenges and Prospective of Actuators
CHAPTER 9: CARBON-BASED ANALOG and DIGITAL ELECTRONICS and CIRCUITS
9.1 Current development on Analog and Digital Electronics
9.2 Radio frequency circuits
9.3 Carbon nanotubes and graphene digital electronics
CHAPTER 10: CONCLUSIONS and FUTURE PERSPECTIVES
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.