Chapter 1��Introduction 001
1.1��Brief introduction to world energy consumption 001
1.2��History of various new energy materials and devices 006
1.2.1��Batteries 006
1.2.2��Supercapacitors 008
1.2.3��Fuel cells 009
1.2.4��Solar cells 010
1.2.5��Biomass energy 012
1.2.6��Nuclear energy 012
1.3��Principles of various new energy materials and devices 013
1.3.1��Principles of metal-ion secondary batteries 013
1.3.2��Principles of other secondary batteries 014
1.3.3��Principles of fuel cells 015
1.3.4��Principles of supercapacitors 017
1.3.5��Principles of solar cells 017
1.3.6��Principles of solar-to-hydrogen 018
1.3.7��Principles of biomass energy 019
1.3.8��Principles of nuclear energy 019
1.4��Some requirements for various new energy materials and devices 020
1.4.1��Requirements for lithium secondary batteries 020
1.4.2��Requirements of other secondary batteries 020
1.4.3��Requirements of fuel cells 022
1.4.4��Requirements of supercapacitors 023
1.4.5��Requirements of solar cells 023
1.4.6��Requirements of solar-to-hydrogen conversion 023
1.4.7��Requirements of biomass energy 024
1.4.8��Requirements of nuclear energy 024
1.5��About this book 024
References 025

Chapter 2��Lithium secondary batteries 028
2.1��Positive electrode materials for LIBs 029
2.1.1��LiCoO2-based positive electrode materials 030
2.1.2��LiNiO2-based positive electrode materials 031
2.1.3��LiMn2O4-based positive electrode materials 032
2.1.4��LiFePO4-based positive electrode materials 034
2.1.5��LiNi1-x-yCoxMnyO2 (NCM) positive electrode materials 034
2.2��Negative electrode materials for LIBs 036
2.2.1��Graphite 036
2.2.2��Si-based materials 038
2.2.3��Titanium oxides 038
2.3��Electrolytes for LIBs 039
2.3.1��Liquid electrolytes 040
2.3.2��Solid electrolytes 043
2.4��Separators for LIBs 045
2.4.1��The functions and characteristics of the separator 045
2.4.2��Separator types 046
2.4.3��Separator preparation methods 047
2.5��Aqueous rechargeable lithium batteries 049
2.5.1��First generation aqueous rechargeable lithium batteries 050
2.5.2��Second generation aqueous rechargeable lithium batteries 051
2.5.3��Third generation aqueous rechargeable lithium batteries 052
2.5.4��Side-reactions with H2O and O2 in an electrolyte 053
2.5.5��Water-in-salt aqueous rechargeable lithium batteries 054
2.6��Li-sulfur batteries 054
2.6.1��Principles of Li-sulfur batteries 055
2.6.2��Sulfur positive electrodes 056
2.6.3��Electrolytes for Li-sulfur batteries 056
2.7��Li-air batteries 057
2.7.1��Water-based lithium-air batteries 059
2.7.2��Organic lithium-air batteries 059
2.7.3��Water-organic two-liquid system lithium-air batteries 059
2.7.4��Solid-state lithium-air batteries 060
2.7.5��Ionic liquid system lithium-air batteries 060
References 060

Chapter 3��Other secondary batteries 065
3.1��Redox flow batteries 065
3.1.1��Polysulfide bromide battery (PSB) 068
3.1.2��ZNBR battery 068
3.1.3��Vanadium redox flow battery (VFB) 069
3.2��Na-S battery 070
3.2.1��Principle of operation 070
3.2.2��The configuration of the NAS battery 072
3.2.3��NAS battery features 073
3.2.4��Composition and crystalline structure of b-alumina 074
3.2.5��Challenges of NAS batteries 075
3.3��Other metal-air batteries 075
References 079

Chapter 4��Fuel cells 082
4.1��Introduction 082
4.1.1��Some history 082
4.1.2��Ordinary fuel cells 083
4.1.3��Advantages and disadvantages of fuel cells 084
4.1.4��Types of fuel cells 087
4.2��Fuel cell thermodynamics 095
4.2.1��How a basic fuel cell works 095
4.2.2��Fuel cell performance 095
4.2.3��Fuel cell internal energy 097
4.2.4��First law of thermodynamics 097
4.2.5��The second law of thermodynamics 098
4.2.6��What are thermodynamic potential and enthalpy 098
4.2.7��The calculation of reaction enthalpy 100
4.2.8��The Gibbs free energy 100
4.2.9��Factors influencing reversible voltage and calculation 101
4.2.10��Ideal fuel cell efficiency and actual fuel cell efficiency 103
4.3��Fuel cell reaction kinetics 104
4.3.1��Current basic physical quantity calculation 104
4.3.2��Calculation of reaction rate 105
4.3.3��Tiffier equation 105
4.3.4��Responsive charge transfer 106
4.3.5��Charge transfer can cause voltage loss 107
4.3.6��The physical significance of conductivity 108
4.4��Fuel cell systems 108
4.4.1��General description of fuel cell systems 108
4.4.2��Fuel cell stack 109
4.4.3��Fuel transfer processing subsystem 110
4.4.4��Power transmission subsystem 111
4.4.5��Fuel cell design levels: the unit cell, the stack, and the system 112
4.5��Fuel cell based power systems 115
4.5.1��Hybrid fuel cell power system 115
4.5.2��Standalone fuel cell power system 116
4.5.3��Grid connected fuel cell power systems 116
4.6��Applications of fuel cells 117
4.6.1��Fuel cell vehicles 117
4.6.2��Telecommunications 118
4.6.3��Underwater vehicles 118
4.6.4��Future targets 118
4.7��Conclusion 119
References 119

Chapter 5��Supercapacitors 123
5.1��Introduction 123
5.2��Charge storage mechanism of supercapacitors 124
5.2.1��Electrochemical double-layer capacitors 124
5.2.2��Pseudocapacitors 127
5.2.3��Hybrid capacitor devices 128
5.3��Electrolytes 129
5.3.1��Aqueous electrolytes 131
5.3.2��Organic electrolytes 132
5.3.3��Ionic-liquid-based electrolytes 135
5.3.4��Solid- and quasi-solid-state electrolytes 135
5.4��Electrode materials for EDLCs 137
5.4.1��Carbon materials with different-scaled pores 137
5.4.2��Activated carbons (ACs) 138
5.4.3��Carbon nanotubes (CNTs) 139
5.4.4��Graphene-based electrode materials 140
5.4.5��Other carbon structures 142
5.5��Electrode materials for pseudocapacitors 143
5.5.1��Noble metal oxides 143
5.5.2��Transition metal oxides and hydroxides 145
5.5.3��Conducting polymers (CPs) 146
5.6��Hybrid capacitors 149
5.6.1��Acidic HCs 149
5.6.2��Alkaline HCs 149
5.6.3��Lithium-ion capacitors 150
5.6.4��Sodium-ion capacitors 151
5.7��Supercapacitor performance 153
5.8��Applications of supercapacitors 154
References 155