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Provides a comprehensive introduction to the field of nanocarbon electrochemistry
The discoveries of new carbon materials such as fullerene, graphene, carbon nanotubes, graphene nanoribbon, carbon dots, and graphdiyne have triggered numerous research advances in the field of electrochemistry. This book brings together up-to-date accounts of the recent progress, developments, and achievements in the electrochemistry of different carbon materials, focusing on their unique properties and various applications.
Nanocarbon Electrochemistry begins by looking at the studies of heterogeneous electron transfer at various carbon electrodes when redox-active molecules are reversibly and specifically adsorbed on the carbon electrode surface. It then covers electrochemical energy storage applications of various carbon materials, particularly the construction and performance of supercapacitors and batteries by use of graphene and related materials. Next, it concentrates on electrochemical energy conversion applications where electrocatalysis at 0D, 1D, 2D, and 3D carbon materials nanocarbon materials is highlighted. The book finishes with an examination of the contents of electrogenerated chemiluminescence and photoelectrochemical pollutant degradation by use of diamond and related carbon materials.
Covers the fundamental properties of different carbon materials and their applications across a wide range of areas
Provides sufficient background regarding different applications, which contributes to the understanding of specialists and non-specialists
Examines nanoelectrochemistry of adsorption-coupled electron transfer at carbon electrodes; graphene and graphene related materials; diamond electrodes for the electrogenerated chemiluminescence; and more
Features contributions from an international team of distinguished researchers
Nanocarbon Electrochemistry is an ideal book for students, researchers, and industrial partners working on many diverse fields of electrochemistry, whether they already make frequent use of carbon electrodes in one form of another or are looking at electrodes for new applications.
Auteur
Editors Nianjun Yang, Institute of Materials Engineering, University of Siegen, Germany Guohua Zhao, School of Chemical Science & Engineering, Shanghai Key Lab of Chemical Assessment and Sustainability, Tongji University, Shanghai, China John S. Foord, Department of Chemistry, Physical & Theoretical Chemistry, University of Oxford, United Kingdom
Texte du rabat
Nanocarbon Electrochemistry Provides a comprehensive introduction to the field of nanocarbon electrochemistry The discoveries of new carbon materials such as fullerene, graphene, carbon nanotubes, graphene nanoribbon, carbon dots, and graphdiyne have triggered numerous research advances in the field of electrochemistry. This book brings together up-to-date accounts of the recent progress, developments, and achievements in the electrochemistry of different carbon materials, focusing on their unique properties and various applications. Nanocarbon Electrochemistry begins by looking at the studies of heterogeneous electron transfer at various carbon electrodes when redox-active molecules are reversibly and specifically adsorbed on the carbon electrode surface. It then covers electrochemical energy storage applications of various carbon materials, particularly the construction and performance of supercapacitors and batteries by use of graphene and related materials. Next, it concentrates on electrochemical energy conversion applications where electrocatalysis at 0D, 1D, 2D, and 3D carbon materials is highlighted. The book finishes with an examination of the contents of electrogenerated chemiluminescence and photoelectrochemical pollutant degradation by use of diamond and related carbon materials.
Contenu
List of Contributors xi
Series Preface xv
Preface xvii
1 Nanoelectrochemistry of Adsorption-Coupled Electron Transfer at Carbon Electrodes **1
Shigeru Amemiya
1.1 Introduction 1
1.2 Overview of Adsorption-Coupled ET 2
1.3 Clean Carbon Electrodes 4
1.4 SECM-Based Nanogap Voltammetry 7
1.5 Adsorption-Coupled Outer-Sphere ET 13
1.6 Self-Inhibition of Outer-Sphere ET 16
1.7 Coupling Between Outer- and Inner-Sphere ET 19
1.8 Resolving Outer- and Inner-Sphere ET 23
1.9 Summary and Perspectives 26
Acknowledgments 26
References 26
2 The Capacitance of Graphene: From Model Systems to Large-Scale Devices **33
Pawin Iamprasertkun and Robert A.W. Dryfe
2.1 Graphene Overview 33
2.2 Introduction to Capacitance 34
2.2.1 Capacitance Model 34
2.2.2 Space Charge Capacitance 36
2.2.3 Quantum Capacitance 37
2.3 Capacitance of Graphene 39
2.4 Formation of Heterostructures: Graphene and Other 2D Materials 43
2.4.1 Transition Metal Dichalcogenides (TMDCs) 43
2.4.2 2D Nanocrystal or MXenes 44
2.4.3 Hexagonal Boron Nitride (h-BN) 46
2.4.4 Phosphorene 47
2.5 Formulation of 3D Graphene Architectures 49
2.5.1 Graphene Sponges 49
2.5.2 Template-Assisted Graphene 49
2.5.3 Graphene Aerogels 51
2.5.4 Pillared Graphene Frameworks (PGFs) 54
2.5.5 Carbon Composites 56
2.6 The Influence of Heteroatom Doping on Graphene 56
2.6.1 Oxygen-Doped Graphene 57
2.6.2 Nitrogen-Doped Graphene 58
2.6.3 Boron-Doped Graphene 61
2.6.4 Use of Other Elements to Dope Graphene 61
2.6.5 Co-doped Graphene 63
2.6.6 Multi-element Doping of Graphene 64
2.7 Application of Graphene in Large-Scale Devices 65
2.7.1 General Principles of Supercapacitors 65
2.7.2 Graphene-Based Supercapacitors and Novel Cell Design 68
2.7.3 Li/Na Ion Capacitors 70
2.8 Summary and Future Outlook 71
References 75
3 Graphene and Related Materials as Anode Materials in Li Ion Batteries: Science and Practicality **85
Sandeep Kumar Marka, Veera Venkata Harish Peruswamula, and Venkata Satya Siva Srikanth Vadali
3.1 Introduction 85
3.2 Graphite as an Anode Material in Li Ion Batteries 86
3.3 Graphene and Related Materials as Anode Material in Li Ion Batteries 89
3.3.1 Graphene and Related Materials as Anode Material in LIBs-Science and Practicality 90
3.3.2 Intercalation-based 91
3.3.2.1 rGO-TiO2 System 91
3.3.2.2 rGO-Li4Ti5O12 System 91
3.3…