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Handbook of Graphene Materials.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Tiwari, Ashutosh
Otros Autores: Ozkan, Cengiz S., Ozkan, Umit S.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Newark : John Wiley & Sons, Incorporated, 2019.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover
  • Title Page
  • Copyright Page
  • Contents
  • Preface
  • 1 Graphene Nanomaterials in Energy and Environment Applications
  • 1.1 Introduction
  • 1.2 Preparations of Graphene-Based Materials
  • 1.2.1 Graphene
  • 1.2.2 Graphene-Based Composites
  • 1.3 Applications of Graphene-Based Materials in Energy and Environment
  • 1.3.1 Solar Cells
  • 1.3.2 Supercapacitors
  • 1.3.3 Gas Sensors
  • 1.3.3.1 Graphene-Based Gas Sensors
  • 1.3.3.2 GO and rGO-Based Gas Sensors
  • 1.3.3.3 Modified Graphene-Based Gas Sensors
  • 1.3.3.4 Graphene/Metal Oxide Hybrid-Based Gas Sensors
  • 1.3.4 Catalysts for Reduction of CO2 and Degradation of Organic Pollutants
  • 1.3.5 Photodetectors
  • 1.4 Conclusion and Outlook
  • Acknowledgments
  • References
  • 2 Graphene as Nanolubricant for Machining
  • 2.1 Introduction
  • 2.2 Tribological Testing of Graphene Nanolubricants
  • 2.3 Machining Using Graphene as Nanolubricant
  • 2.3.1 Application of Graphene in Milling Operations
  • 2.3.2 Application of Graphene in Drilling and Tapping Operations
  • 2.3.3 Application of Graphene in Turning Operations
  • 2.3.4 Application of Graphene in Grinding Operations
  • 2.3.5 Electro Discharge Machining Using Graphenes
  • 2.4 Conclusion and Outlook
  • References
  • 3 Three-Dimensional Graphene Foams for Energy Storage Applications
  • 3.1 Introduction
  • 3.2 Fabrication, Structure, and Performance of GF
  • 3.2.1 Self-Assembly Method
  • 3.2.2 Template-Guide Method
  • 3.2.3 3D Printing Method
  • 3.2.4 Performance of GF
  • 3.3 Applications of GF in Energy Storage Devices
  • 3.3.1 Batteries
  • 3.3.1.1 Metal-Ion Batteries
  • 3.3.1.2 Metal-Sulfur Batteries
  • 3.3.1.3 Metal-Air Batteries
  • 3.3.2 Supercapacitors
  • 3.3.2.1 Electric Double-Layer Supercapacitors
  • 3.3.2.2 Pseudocapacitors
  • 3.4 Conclusions and Outlook
  • References.
  • 4 Three-Dimensional Graphene Materials: Synthesis and Applications in Electrocatalysts and Electrochemical Sensors
  • 4.1 Introduction
  • 4.2 Synthesis of 3D Graphene-Based Materials
  • 4.2.1 Chemical Self-Assembly
  • 4.2.1.1 Adding Different Precursors during the 3D Graphene Preparation Procedures
  • 4.2.1.2 3D Graphene as a Carbon Support
  • 4.2.2 Template-Assisted Assembly by Chemical Method
  • 4.2.3 Template-Assisted Assembly by CVD
  • 4.2.4 3D Printing
  • 4.3 Electrocatalytic Activity of 3D Graphene-Based Materials
  • 4.3.1 3D Graphene-Based Materials for ORR
  • 4.3.2 3D Graphene-Based Materials for MOR
  • 4.3.2.1 Pt Nanoparticles Supported on 3D Graphene
  • 4.3.2.2 Pt-Based Alloy Nanoparticles Supported on 3D Graphene
  • 4.3.2.3 Nonplatinum Nanoparticles Supported on 3D Graphene
  • 4.3.3 3D Graphene-Based Materials for EOR
  • 4.3.4 3D Graphene-Based Materials for FAOR
  • 4.3.5 3D Graphene-Based Materials for HER
  • 4.3.5.1 3D Graphene for HER
  • 4.3.5.2 3D Graphene as a Carbon Support for HER
  • 4.3.6 3D Graphene-Based Materials for OER
  • 4.3.7 3D Graphene-Based Materials for CO2 Reduction
  • 4.4 Electrochemical Sensing Properties of 3D Graphene-Based Materials
  • 4.4.1 3D Graphene-Based Materials for Heavy Metal Ions Sensing
  • 4.4.2 3D Graphene-Based Materials for H2O2 Sensing
  • 4.4.3 3D Graphene-Based Materials for Glucose Sensing
  • 4.4.4 3D Graphene-Based Materials for Dopamine Sensing
  • 4.4.5 3D Graphene-Based Materials for Urea Sensing
  • 4.4.6 3D Graphene-Based Materials for Other Molecules Sensing
  • 4.5 Conclusion
  • Acknowledgments
  • References
  • 5 Graphene and Graphene-Based Hybrid Composites for Advanced Rechargeable Battery Electrodes
  • 5.1 Introduction
  • 5.2 Li-Ion Batteries
  • 5.2.1 Graphene and Its Derivatives as Active Materials for LIB Anodes
  • 5.2.2 Graphene-Based Composites for LIB Anodes.
  • 5.2.2.1 Graphene with Alloy-Based Materials
  • 5.2.2.2 Graphene with Transition Metal Oxides
  • 5.2.2.3 Graphene with Titanium-Based Compounds
  • 5.2.3 Graphene-Based Composites for LIB Cathodes
  • 5.3 Na-Ion Batteries
  • 5.3.1 Graphene and Its Derivatives as Active Materials for NIB Anodes
  • 5.3.2 Graphene-Based Composites for NIB Anodes
  • 5.3.2.1 Graphene with Alloy-Based Materials
  • 5.3.2.2 Graphene with Metal Oxides/Sulfides
  • 5.3.2.3 Graphene with Titanium-Based Compounds
  • 5.3.3 Graphene-Based Composites for NIB Cathodes
  • 5.4 Li-S Batteries
  • 5.4.1 Sulfur with Graphene
  • 5.4.2 Graphene Derivatives as an Interlayer Membrane
  • 5.5 Li-Air Batteries
  • 5.5.1 Graphene as an Electrocatalyst
  • 5.5.2 Graphene as a Supporting Matrix
  • 5.6 Summary and Perspectives
  • References
  • 6 Graphene-Based Materials for Advanced Lithium-Ion Batteries
  • 6.1 Introduction of Lithium-Ion Batteries
  • 6.2 Graphene and Its Properties
  • 6.3 Synthesis Methods of Graphene for LIBs
  • 6.3.1 Graphene Preparation
  • 6.3.2 Exfoliation and Reduction from Graphite Oxide
  • 6.3.3 CVD to Prepare Graphene
  • 6.4 Graphene-Based Composites for LIBs
  • 6.4.1 Graphene for LIB Anode
  • 6.4.2 Graphene-Based Composites as Anode
  • 6.4.3 Graphene-Based Metal Li Anode
  • 6.4.4 Graphene-Based Composites as Cathode
  • 6.5 Graphene-Based Composites for Li-S Batteries
  • 6.5.1 Li-S Batteries
  • 6.5.2 Graphene-Based Composites for Li-S Batteries
  • 6.6 Graphene-Based Composites for Li-O2 Batteries
  • 6.6.1 Li-O2 Batteries
  • 6.6.2 Graphene and Graphene-Based Composites for Li-O2 Batteries
  • 6.7 Conclusions and Outlook
  • References
  • 7 Graphene-Based Materials for Supercapacitors and Conductive Additives of Lithium Ion Batteries
  • 7.1 Introduction
  • 7.1.1 Historical Background
  • 7.1.2 Principle of Supercapacitor
  • 7.1.2.1 Electrochemical Double-Layer Capacitor (EDLC).
  • 7.1.2.2 Pseudocapacitance
  • 7.1.3 Carbon Materials for Supercapacitor
  • 7.1.3.1 Activated Carbon
  • 7.1.3.2 Carbon Nanotubes
  • 7.1.3.3 Graphene
  • 7.1.3.4 Other Carbon Structure
  • 7.1.4 Applications
  • 7.1.5 Motivation and Objective
  • 7.2 Experimental Technique
  • 7.2.1 Electrochemical Methods
  • 7.2.1.1 Cyclic Voltammetry
  • 7.2.1.2 Constant Current Charge and Discharge
  • 7.2.1.3 Electrochemical Impedance Spectroscopy
  • 7.2.2 Test Cell Configuration
  • 7.2.3 Measurement Procedure
  • 7.2.4 Summary of Test Method
  • 7.3 Graphene and Carbon Nanotube Composite Materials
  • 7.3.1 Introduction
  • 7.3.2 Experimental
  • 7.3.3 Results and Discussion
  • 7.3.4 Conclusions
  • 7.4 Graphene and Nanostructured MnO2 Composite Electrode
  • 7.4.1 Introduction
  • 7.4.2 Experimental
  • 7.4.2.1 Graphene Oxide
  • 7.4.2.2 Reduction of Graphene Oxide
  • 7.4.2.3 In Situ MnO2 Electrodeposition
  • 7.4.2.4 Fabrication of Test Cells
  • 7.4.2.5 Electrochemical Measurement
  • 7.4.2.6 Structural Characterization
  • 7.4.3 Results and Discussion
  • 7.4.3.1 Morphology of Graphene and MnO2-Coated Graphene
  • 7.4.3.2 Electrochemical Behavior
  • 7.4.4 Conclusions
  • 7.5 Polyaniline Nanocone-Coated Graphene and Carbon Nanotube Composite Electrode
  • 7.5.1 Introduction
  • 7.5.2 Experimental
  • 7.5.2.1 Graphene Oxide
  • 7.5.2.2 Reduction of Graphene Oxide
  • 7.5.2.3 Graphene/CNT/Polyaniline Composite Material
  • 7.5.2.4 Electrochemical and Structural Characterization
  • 7.5.3 Results and Discussion
  • 7.5.4 Conclusions
  • 7.6 Electrodeposition of Nanoporous Cobalt Hydroxide on Graphene and Carbon Nanotube Composites
  • 7.6.1 Introduction
  • 7.6.2 Experimental
  • 7.6.3 Results and Discussion
  • 7.6.4 Conclusions
  • 7.7 Porous Graphene Sponge Additives for Lithium Ion Batteries with Excellent Rate Capability
  • 7.7.1 Introduction
  • 7.7.2 Methods
  • 7.7.2.1 Synthesis of Magic G.
  • 7.7.2.2 Characterization
  • 7.7.2.3 Cell Fabrication
  • 7.7.3 Results and Discussion
  • 7.7.4 Conclusion
  • 7.8 Conclusions and Perspective
  • 7.8.1 Conclusions
  • 7.8.1.1 Graphene and Carbon Nanotube Composite Materials
  • 7.8.1.2 Graphene and Nanostructured MnO2 Composite Materials
  • 7.8.1.3 Polyaniline Nanocone-Coated Graphene and Carbon Nanotube Composite Electrode
  • 7.8.1.4 Electrodeposition of Nanoporous Cobalt Hydroxide on Graphene and Carbon
  • 7.8.1.5 Porous Graphene Sponge Additives for Lithium Ion Batteries with Excellent Rate Capability
  • 7.8.2 Future Prospects
  • References
  • 8 Graphene-Based Flexible Actuators, Sensors, and Supercapacitors
  • 8.1 Introduction
  • 8.2 IPGC Transducer for Actuators, Sensors, and Supercapacitors-Background and Basics
  • 8.3 Electrochemical Actuators
  • 8.3.1 Large Volume Expansion of Pristine Graphene-Based Actuators
  • 8.3.2 Highly Durable Graphene Hybrid-Based Actuators
  • 8.3.3 High Strain Rate Heterogeneous Doped Graphene-Based Actuators
  • 8.3.4 Graphene Surface and Device Interface
  • 8.4 Piezoionic Sensors
  • 8.4.1 Largely Increased Response Signal of Pristine Graphene-Based Sensors
  • 8.4.2 Highly Sensitive Holey-Graphene-Based Sensors
  • 8.4.3 Passive Property and Space Recognition of Graphene Sensors
  • 8.5 Supercapacitors
  • 8.5.1 High Energy Storage Capacity of Graphene-Based Supercapacitors
  • 8.5.2 Highly Flexible Graphene Hybrid-Based Supercapacitors
  • 8.5.3 Unconventional Graphene-Based Supercapacitors
  • 8.6 Summary and Future Development
  • Acknowledgments
  • References
  • 9 Graphene as Catalyst Support for the Reactions in Fuel Cells
  • Acronyms
  • 9.1 Introduction
  • 9.2 Synthesis of Graphene
  • 9.3 Structural Properties and Functionalization of Graphene
  • 9.4 Structural Characterizations of Graphene
  • 9.5 Graphene Morphology
  • 9.6 Carbon Materials as Catalyst Support.