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Submit a ProposalEnergy |
Zinc Batteries
 | Basics, Developments, and Applications Edited by Rajender Boddula, Inamuddin, and Abdullah M. Asiri Copyright: 2020 | Status: Published ISBN: 9781119661894 | Hardcover | 268 pages Price: $225 USD  |
One Line Description
Edited by one of the most well-respected and prolific engineers in the world and his team, this is the most thorough, up-to-date, and comprehensive volume on zinc batteries available today.
Audience
Engineers, researchers, professionals, and graduate students in batteries and material science and nanotechnology, including engineers in areas such as chemical, environmental, biomedical, and electrical engineering
Engineers, researchers, professionals, and graduate students in batteries and material science and nanotechnology, including engineers in areas such as chemical, environmental, biomedical, and electrical engineering
Description
Battery technology is constantly changing, and the concepts and applications of these changes are rapidly becoming increasingly more important as more and more industries and individuals continue to make “greener” choices in their energy sources. As global dependence on fossil fuels slowly wanes, there is a heavier and heavier importance placed on cleaner power sources and methods for storing and transporting that power. Battery technology is a huge part of this global energy revolution.
Zinc batteries are an advantageous choice over lithium-based batteries, which have dominated the market for years in multiple areas, most specifically in electric vehicles and other battery-powered devices. Zinc is the fourth most abundant metal in the world, which is influential in its lower cost, making it a very attractive material for use in batteries. Zinc-based batteries have been around since the 1930s, but only now are they taking center stage in the energy, automotive, and other industries.
Zinc Batteries: Basics, Developments, and Applications is intended as a discussion of the different zinc batteries for energy storage applications. It also provides an in-depth description of various energy storage materials for Zinc (Zn) batteries. This book is an invaluable reference guide for electro¬chemists, chemical engineers, students, faculty, and R&D professionals in energy storage science, material science, and renewable energy.
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Battery technology is constantly changing, and the concepts and applications of these changes are rapidly becoming increasingly more important as more and more industries and individuals continue to make “greener” choices in their energy sources. As global dependence on fossil fuels slowly wanes, there is a heavier and heavier importance placed on cleaner power sources and methods for storing and transporting that power. Battery technology is a huge part of this global energy revolution.
Zinc batteries are an advantageous choice over lithium-based batteries, which have dominated the market for years in multiple areas, most specifically in electric vehicles and other battery-powered devices. Zinc is the fourth most abundant metal in the world, which is influential in its lower cost, making it a very attractive material for use in batteries. Zinc-based batteries have been around since the 1930s, but only now are they taking center stage in the energy, automotive, and other industries.
Zinc Batteries: Basics, Developments, and Applications is intended as a discussion of the different zinc batteries for energy storage applications. It also provides an in-depth description of various energy storage materials for Zinc (Zn) batteries. This book is an invaluable reference guide for electro¬chemists, chemical engineers, students, faculty, and R&D professionals in energy storage science, material science, and renewable energy.
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Supplementary Data
• Covers the basic research and application approaches to zinc batteries
• Explores challenges and future directions of zinc batteries
• Outlines the influences of electrodes and electrolytes for enhanced performance
• Includes all types of energy storage materials in a single volume
• Elaborates on the extensive properties of zinc batteries electrodes for future use
• Covers the basic research and application approaches to zinc batteries
• Explores challenges and future directions of zinc batteries
• Outlines the influences of electrodes and electrolytes for enhanced performance
• Includes all types of energy storage materials in a single volume
• Elaborates on the extensive properties of zinc batteries electrodes for future use
Author / Editor Details
Rajender Boddula, PdD, is currently working for the Chinese Academy of Sciences President’s International Fellowship Initiative (CAS-PIFI) at the National Center for Nanoscience and Technology (NCNST, Beijing). His academic honors include multiple fellowships and scholarships, and he has published many scientific articles in international peer-reviewed journals. He is also serving as an editorial board member and a referee for several reputed international peer-reviewed journals. He has published edited books with numerous publishers and has authored twenty book chapters.
Rajender Boddula, PdD, is currently working for the Chinese Academy of Sciences President’s International Fellowship Initiative (CAS-PIFI) at the National Center for Nanoscience and Technology (NCNST, Beijing). His academic honors include multiple fellowships and scholarships, and he has published many scientific articles in international peer-reviewed journals. He is also serving as an editorial board member and a referee for several reputed international peer-reviewed journals. He has published edited books with numerous publishers and has authored twenty book chapters.
Inamuddin, PhD, is an assistant professor at King Abdulaziz University, Jeddah, Saudi Arabia and is also an assistant professor in the Department of Applied Chemistry, Aligarh Muslim University, Aligarh, India. He has extensive research experience in multidisciplinary fields of analytical chemistry, materials chemistry, electrochemistry, renewable energy and environmental science. He has worked on different research projects funded by various government agencies and universities and is the recipient of awards, including the Fast Track Young Scientist Award. He has published about 150 research articles in various international scientific journals, 18 book chapters, and 60 edited books with multiple well-known publishers. His current research interests include ion exchange materials, a sensor for heavy metal ions, biofuel cells, supercapacitors and bending actuators.
Abdullah M. Asiri is the Head of the Chemistry Department at King Abdulaziz University and the founder and Director of the Center of Excellence for Advanced Materials Research (CEAMR). He is the Editor-in-Chief of the King Abdulaziz University Journal of Science. He has received numerous awards, including the “Young Scientist Award” from the Saudi Chemical Society in 2009 and the first prize for the distinction in science from the Saudi Chemical Society in 2012. He serves on the editorial boards of multiple scientific journals and is the Vice President of the Saudi Chemical Society (Western Province Branch). He holds multiple patents, has authored ten books, more than one thousand publications in international journals, and multiple book chapters.
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Table of Contents
1 Carbon Nanomaterials for Zn-Ion Batteries 1
Prasun Banerjee, Adolfo Franco Jr, Rajender Boddula,
K. Chandra Babu Naidu and Ramyakrishna Pothu
1.1 Introduction 2
1.2 Co4N (CN) - Carbon Fibers Network (CFN) -
Carbon Cloth (CC) 2
1.3 N-Doping of Carbon Nanofibers 2
1.4 NiCo2S4 on Nitrogen-Doped Carbon Nanotubes 4
1.5 3D Phosphorous and Sulfur Co-Doped C3N4 Sponge With C Nanocrystal 5
1.6 2D Carbon Nanosheets 6
1.7 N-Doped Graphene Oxide With NiCo2O4 6
1.8 Conclusions 7
Acknowledgements 8
References 8
2 Construction, Working, and Applications of Different
Zn-Based Batteries 11
G. Ranjith Kumar, K. Chandra Babu Naidu, D. Baba Basha, D. Prakash Babu, M.S.S.R.K.N. Sarma, Ramyakrishna Pothu, and Rajender Boddula
2.1 Introduction 11
2.2 History 13
2.3 Types of Batteries 14
2.3.1 Primary Battery 14
2.3.2 Secondary Battery 14
2.4 Zinc-Carbon Batteries 18
2.5 Zinc-Cerium Batteries 19
2.6 Zinc-Bromine Flow Batteries 20
References 21
3 Nickel and Cobalt Materials for Zn Batteries 25
Sonal Singh, Rishabh Sharma and Manika Khanuja
3.1 Introduction 26
3.2 Zinc Batteries 27
3.3 Nickel-Zinc Battery 27
3.3.1 History 27
3.3.2 Basics 28
3.3.3 Materials and Cost 30
3.3.4 Reliability 30
3.3.5 Voltage Drop 30
3.3.6 Performance 31
3.4 Advantages 31
3.5 Challenges 32
3.6 Effect of Metallic Additives, Cobalt and Zinc, on Nickel Electrode 32
3.7 Conclusion 33
References 34
4 Manganese-Based Materials for Zn Batteries 37
S. Ramesh, K. Chandrababu Naidu, K. Venkata Ratnam, H. Manjunatha, D. Baba Basha and A. Mallikarjauna
4.1 Introduction 37
4.2 History of the Zinc and Zinc Batteries 38
4.3 Characteristics of Batteries 41
4.3.1 Capacity 41
4.3.2 Current 41
4.3.3 Power Density 41
4.4 MN-Based Zn Batteries 42
4.5 Conclusion 44
References 47
5 Electrolytes for Zn-Ion Batteries 51
Praveen Kumar Yadav, Sapna Raghav, Jyoti Raghav
and S. S. Swarupa Tripathy
5.1 Introduction 52
5.2 Electrolytes for RZIB 53
5.2.1 Aqueous Electrolytes 54
5.2.1.1 Pros and Cons of AEs 55
5.2.1.2 Neutral or Mildly Acidic Electrolytes 58
5.2.2 Non-Aqueous Electrolytes 59
5.2.2.1 Solid Polymer Electrolytes 60
5.2.2.2 Hydrogel or Gel Electrolytes 61
5.2.2.3 Gel Polymer Electrolytes 63
5.2.3 Ionic Liquid Electrolytes 63
5.2.4 Bio-Electrolyte 65
5.3 Summary 65
Abbreviation Table 66
Acknowledgments 66
References 67
6 Anode Materials for Zinc-Ion Batteries 73
Muhammad Mudassir Hassan, Muhammad Inam Khan, Abdur Rahim and Nawshad Muhammad
6.1 Introduction 73
6.2 Storage Mechanism 75
6.3 Zinc-Ion Battery Anodes 77
6.4 Future Prospects 81
6.5 Conclusion 81
References 82
7 Cathode Materials for Zinc-Air Batteries 85
Seyedeh Maryam Mousavi and Mohammad Reza Rahimpour
7.1 Introduction 85
7.1.1 Cathode Definition 86
7.2 Zinc Cathode Structure 87
7.3 Non-Valuable Materials for Cathode Electrocatalytic 89
7.4 Electrochemical Specifications of Activated
Carbon as a Cathode 92
7.4.1 Electrochemical Evaluation of Cathode
Substances La1−XCaxCoO3 Zinc Batteries 92
7.5 Extremely Durable and Inexpensive Cathode Air Catalyst 93
7.5.1 Co3O4/Mno2 NPs Dual Oxygen Catalyst as
Cathode for Zn-Air Rechargeable Battery 94
7.5.2 Carbon Nanotubes (CNT) Employing Nitrogen as Catalyst in the Zinc/Air Battery System 94
7.5.3 Magnesium Oxide NPs Modified Catalyst for the
Use of Air Electrodes in Zn/Air Batteries 94
7.5.4 Silver-Magnesium Oxide Nanocatalysts as Cathode
for Zn-Air Batteries 95
7.5.5 One-Step Preparation of C-N Ni/Co-Doped Nanotube Hybrid as Outstanding Cathode Catalysts for
Zinc-Air Batteries 95
7.6 Hierarchical Co3O4 Nano-Micro Array With Superior
Working Characteristics Using Cathode Ray on Pliable and Rechargeable Battery 96
7.7 Dual Function Oxygen Catalyst Upon Active Iron-Based
Zn-Air Rechargeable Batteries 97
7.7.1 Co4N and NC Fiber Coupling Connected to a
Free-Acting Binary Cathode for Strong, Efficient, and Pliable Air Batteries 98
7.8 Conclusion 98
Nomenclature 99
References 99
8 Anode Materials for Zinc-Air Batteries 103
Abbas Ghareghashi and Ali Mohebbi
8.1 Introduction 104
8.2 Zinc Anodes 105
8.2.1 Downsizing of Zn Anodes 106
8.2.2 Design of Membrane Separators 107
8.2.3 The Use of ZnO Instead of Zn 108
8.2.4 Increase of Surface Area in Zn Anode Structure 110
8.2.5 Coating of Zn Anode 111
8.2.5.1 Bismuth Oxide-Based Glasses 112
8.2.5.2 Silica 114
8.2.5.3 Carbon Nanotubes 115
8.2.5.4 ZnO@C 116
8.2.5.5 Zn-Al LDHs 116
8.2.5.6 ZnO@C-ZnAl LDHs 118
8.2.5.7 Tapioca 119
8.2.5.8 TiO2 122
8.3 Conclusions 123
References 124
9 Safety and Environmental Impacts in Zn Batteries 131
Saurabh Sharma, Abhishek Anand, Amritanshu Shukla and Atul Sharma
9.1 Introduction 131
9.2 Working Principle of Zinc-Based Batteries 132
9.2.1 Zinc-Air Batteries Basic Principle and Advances 133
9.2.2 Zinc Organic Polymer Batteries 135
9.2.3 Zinc-Ion Batteries 137
9.2.3.1 Zinc-Silver Batteries 137
9.2.3.2 Zinc-Nickel Batteries 138
9.2.3.3 Zinc-Manganese Battery 140
9.3 Batteries: Environment Impact, Solution, and Safety 141
9.3.1 Disposal of Batteries and Environmental Impact 143
9.3.2 Recycling of Zinc-Based Batteries 143
9.4 Conclusion 146
References 147
10 Basics and Developments of Zinc-Air Batteries 151
Seyedeh Maryam Mousavi and Mohammad Reza Rahimpour
10.1 Introduction 151
10.1.1 Public Specifications 151
10.2 Zinc-Air Electrode Chemical Reaction 153
10.3 Zinc/Air Battery Construction 154
10.4 Primary Zn/Air Batteries 157
10.5 Principles of Configuration and Operation 159
10.6 Developments in Electrical Fuel Zn/Air Batteries 161
10.6.1 Zn/Air Versus Metal/Air Systems 161
10.7 Conclusion 162
References 164
11 History and Development of Zinc Batteries 167
Pallavi Jain, Sapna Raghav, Ankita Dhillon and Dinesh Kumar
11.1 Introduction 167
11.2 Basic Concept 169
11.2.1 Components of Batteries 169
11.2.2 Classification of Batteries 171
11.2.2.1 Primary Batteries 171
11.2.2.2 Secondary or Rechargeable
Batteries (RBs) 171
11.3 Cell Operation 172
11.3.1 Process of Discharge 172
11.3.2 Process of Charge 172
11.4 History 173
11.5 Different Types of Zinc Batteries 174
11.5.1 Zinc-Carbon Batteries 174
11.5.2 Zinc/Manganese Oxide Batteries
(Alkaline Batteries) 174
11.5.3 Zinc/Silver Oxide Battery 174
11.5.4 Zn-Air (Zn-O2) Batteries 176
11.5.4.1 Mechanically Rechargeable Batteries
(Zn-O2 Batteries) 177
11.5.4.2 Electrically Rechargeable Batteries
(Zn-O2 Batteries) 178
11.5.5 Hybrid Zn-O2 Batteries 178
11.5.5.1 Hybrid Zn-Ni/O2 Batteries 178
11.5.5.2 Hybrid Zn-Co/O2 Batteries 179
11.5.6 Aqueous Zinc-Ion Rechargeable Batteries 180
11.5.6.1 Insertion/Extraction Mechanism 180
11.5.6.2 Chemical Conversion Mechanism 180
11.5.6.3 H+ and Zn2+ Insertion/Extraction Mechanism 181
11.6 Future Perspectives 181
11.7 Conclusion 182
Abbreviations 182
Acknowledgement 183
References 183
12 Electrolytes for Zinc-Air Batteries 187
Zahra Farmani, Mohammad Amin Sedghamiz,
and Mohammad Reza Rahimpour
12.1 Introduction 187
12.2 Aqueous Electrolytes 188
12.2.1 Alkaline Electrolytes 189
12.2.1.1 Dissolution of Zinc in Alkaline Systems 189
12.2.1.2 Insoluble Carbonates Precipitation 192
12.2.1.3 Effect of Water 193
12.2.1.4 Hydrogen Evolution 194
12.2.2 Neutral Electrolytes 195
12.2.3 Acidic Electrolytes 196
12.3 Electrolytes of Non-Aqueous 197
12.3.1 Non-Aqueous Electrolytes 199
12.3 Summary 203
References 206
13 Safety and Environmental Impact of Zinc Battery 215
ManjuYadav and Dinesh Kumar
13.1 Introduction 215
13.2 Security of Zinc Battery 217
13.2.1 Modifications for Improving Performance 218
13.2.1.1 High Surface Area 218
13.2.1.2 Carbon-Based Electrode Additives 221
13.2.1.3 Discharge-Capturing Electrode
Additives 221
13.2.1.4 Electrode Coatings 222
13.2.1.5 Electrolyte Additives 222
13.2.1.6 Heavy-Metals Electrode Additive 222
13.2.1.7 Polymeric Binders 223
13.2.2 Storage and Handling 224
13.3 Influence of Zinc Battery 224
13.3.1 Consumption of Natural Resources 225
13.3.2 Toxicity of Batteries to Humans 226
13.3.3 Toxicity of Batteries to the Aquatic Environment 226
13.4 Disposal/Recycling Options 227
Acknowledgement 228
References 228
14 Materials for Ni-Zn Batteries 235
Vaishali Tomar and Dinesh Kumar
14.1 Introduction 235
14.1.1 Functioning Principles of Nickel-Zinc Battery 237
14.1.2 Ni-Zn Battery Design 238
14.2 Expansion of Ni-Zn Battery 239
14.2.1 Active Materials for the Battery 240
14.3 Application 241
14.4 Conclusion 242
Acknowledgement 243
References 243
Index 249
Back to Top
1 Carbon Nanomaterials for Zn-Ion Batteries 1
Prasun Banerjee, Adolfo Franco Jr, Rajender Boddula,
K. Chandra Babu Naidu and Ramyakrishna Pothu
1.1 Introduction 2
1.2 Co4N (CN) - Carbon Fibers Network (CFN) -
Carbon Cloth (CC) 2
1.3 N-Doping of Carbon Nanofibers 2
1.4 NiCo2S4 on Nitrogen-Doped Carbon Nanotubes 4
1.5 3D Phosphorous and Sulfur Co-Doped C3N4 Sponge With C Nanocrystal 5
1.6 2D Carbon Nanosheets 6
1.7 N-Doped Graphene Oxide With NiCo2O4 6
1.8 Conclusions 7
Acknowledgements 8
References 8
2 Construction, Working, and Applications of Different
Zn-Based Batteries 11
G. Ranjith Kumar, K. Chandra Babu Naidu, D. Baba Basha, D. Prakash Babu, M.S.S.R.K.N. Sarma, Ramyakrishna Pothu, and Rajender Boddula
2.1 Introduction 11
2.2 History 13
2.3 Types of Batteries 14
2.3.1 Primary Battery 14
2.3.2 Secondary Battery 14
2.4 Zinc-Carbon Batteries 18
2.5 Zinc-Cerium Batteries 19
2.6 Zinc-Bromine Flow Batteries 20
References 21
3 Nickel and Cobalt Materials for Zn Batteries 25
Sonal Singh, Rishabh Sharma and Manika Khanuja
3.1 Introduction 26
3.2 Zinc Batteries 27
3.3 Nickel-Zinc Battery 27
3.3.1 History 27
3.3.2 Basics 28
3.3.3 Materials and Cost 30
3.3.4 Reliability 30
3.3.5 Voltage Drop 30
3.3.6 Performance 31
3.4 Advantages 31
3.5 Challenges 32
3.6 Effect of Metallic Additives, Cobalt and Zinc, on Nickel Electrode 32
3.7 Conclusion 33
References 34
4 Manganese-Based Materials for Zn Batteries 37
S. Ramesh, K. Chandrababu Naidu, K. Venkata Ratnam, H. Manjunatha, D. Baba Basha and A. Mallikarjauna
4.1 Introduction 37
4.2 History of the Zinc and Zinc Batteries 38
4.3 Characteristics of Batteries 41
4.3.1 Capacity 41
4.3.2 Current 41
4.3.3 Power Density 41
4.4 MN-Based Zn Batteries 42
4.5 Conclusion 44
References 47
5 Electrolytes for Zn-Ion Batteries 51
Praveen Kumar Yadav, Sapna Raghav, Jyoti Raghav
and S. S. Swarupa Tripathy
5.1 Introduction 52
5.2 Electrolytes for RZIB 53
5.2.1 Aqueous Electrolytes 54
5.2.1.1 Pros and Cons of AEs 55
5.2.1.2 Neutral or Mildly Acidic Electrolytes 58
5.2.2 Non-Aqueous Electrolytes 59
5.2.2.1 Solid Polymer Electrolytes 60
5.2.2.2 Hydrogel or Gel Electrolytes 61
5.2.2.3 Gel Polymer Electrolytes 63
5.2.3 Ionic Liquid Electrolytes 63
5.2.4 Bio-Electrolyte 65
5.3 Summary 65
Abbreviation Table 66
Acknowledgments 66
References 67
6 Anode Materials for Zinc-Ion Batteries 73
Muhammad Mudassir Hassan, Muhammad Inam Khan, Abdur Rahim and Nawshad Muhammad
6.1 Introduction 73
6.2 Storage Mechanism 75
6.3 Zinc-Ion Battery Anodes 77
6.4 Future Prospects 81
6.5 Conclusion 81
References 82
7 Cathode Materials for Zinc-Air Batteries 85
Seyedeh Maryam Mousavi and Mohammad Reza Rahimpour
7.1 Introduction 85
7.1.1 Cathode Definition 86
7.2 Zinc Cathode Structure 87
7.3 Non-Valuable Materials for Cathode Electrocatalytic 89
7.4 Electrochemical Specifications of Activated
Carbon as a Cathode 92
7.4.1 Electrochemical Evaluation of Cathode
Substances La1−XCaxCoO3 Zinc Batteries 92
7.5 Extremely Durable and Inexpensive Cathode Air Catalyst 93
7.5.1 Co3O4/Mno2 NPs Dual Oxygen Catalyst as
Cathode for Zn-Air Rechargeable Battery 94
7.5.2 Carbon Nanotubes (CNT) Employing Nitrogen as Catalyst in the Zinc/Air Battery System 94
7.5.3 Magnesium Oxide NPs Modified Catalyst for the
Use of Air Electrodes in Zn/Air Batteries 94
7.5.4 Silver-Magnesium Oxide Nanocatalysts as Cathode
for Zn-Air Batteries 95
7.5.5 One-Step Preparation of C-N Ni/Co-Doped Nanotube Hybrid as Outstanding Cathode Catalysts for
Zinc-Air Batteries 95
7.6 Hierarchical Co3O4 Nano-Micro Array With Superior
Working Characteristics Using Cathode Ray on Pliable and Rechargeable Battery 96
7.7 Dual Function Oxygen Catalyst Upon Active Iron-Based
Zn-Air Rechargeable Batteries 97
7.7.1 Co4N and NC Fiber Coupling Connected to a
Free-Acting Binary Cathode for Strong, Efficient, and Pliable Air Batteries 98
7.8 Conclusion 98
Nomenclature 99
References 99
8 Anode Materials for Zinc-Air Batteries 103
Abbas Ghareghashi and Ali Mohebbi
8.1 Introduction 104
8.2 Zinc Anodes 105
8.2.1 Downsizing of Zn Anodes 106
8.2.2 Design of Membrane Separators 107
8.2.3 The Use of ZnO Instead of Zn 108
8.2.4 Increase of Surface Area in Zn Anode Structure 110
8.2.5 Coating of Zn Anode 111
8.2.5.1 Bismuth Oxide-Based Glasses 112
8.2.5.2 Silica 114
8.2.5.3 Carbon Nanotubes 115
8.2.5.4 ZnO@C 116
8.2.5.5 Zn-Al LDHs 116
8.2.5.6 ZnO@C-ZnAl LDHs 118
8.2.5.7 Tapioca 119
8.2.5.8 TiO2 122
8.3 Conclusions 123
References 124
9 Safety and Environmental Impacts in Zn Batteries 131
Saurabh Sharma, Abhishek Anand, Amritanshu Shukla and Atul Sharma
9.1 Introduction 131
9.2 Working Principle of Zinc-Based Batteries 132
9.2.1 Zinc-Air Batteries Basic Principle and Advances 133
9.2.2 Zinc Organic Polymer Batteries 135
9.2.3 Zinc-Ion Batteries 137
9.2.3.1 Zinc-Silver Batteries 137
9.2.3.2 Zinc-Nickel Batteries 138
9.2.3.3 Zinc-Manganese Battery 140
9.3 Batteries: Environment Impact, Solution, and Safety 141
9.3.1 Disposal of Batteries and Environmental Impact 143
9.3.2 Recycling of Zinc-Based Batteries 143
9.4 Conclusion 146
References 147
10 Basics and Developments of Zinc-Air Batteries 151
Seyedeh Maryam Mousavi and Mohammad Reza Rahimpour
10.1 Introduction 151
10.1.1 Public Specifications 151
10.2 Zinc-Air Electrode Chemical Reaction 153
10.3 Zinc/Air Battery Construction 154
10.4 Primary Zn/Air Batteries 157
10.5 Principles of Configuration and Operation 159
10.6 Developments in Electrical Fuel Zn/Air Batteries 161
10.6.1 Zn/Air Versus Metal/Air Systems 161
10.7 Conclusion 162
References 164
11 History and Development of Zinc Batteries 167
Pallavi Jain, Sapna Raghav, Ankita Dhillon and Dinesh Kumar
11.1 Introduction 167
11.2 Basic Concept 169
11.2.1 Components of Batteries 169
11.2.2 Classification of Batteries 171
11.2.2.1 Primary Batteries 171
11.2.2.2 Secondary or Rechargeable
Batteries (RBs) 171
11.3 Cell Operation 172
11.3.1 Process of Discharge 172
11.3.2 Process of Charge 172
11.4 History 173
11.5 Different Types of Zinc Batteries 174
11.5.1 Zinc-Carbon Batteries 174
11.5.2 Zinc/Manganese Oxide Batteries
(Alkaline Batteries) 174
11.5.3 Zinc/Silver Oxide Battery 174
11.5.4 Zn-Air (Zn-O2) Batteries 176
11.5.4.1 Mechanically Rechargeable Batteries
(Zn-O2 Batteries) 177
11.5.4.2 Electrically Rechargeable Batteries
(Zn-O2 Batteries) 178
11.5.5 Hybrid Zn-O2 Batteries 178
11.5.5.1 Hybrid Zn-Ni/O2 Batteries 178
11.5.5.2 Hybrid Zn-Co/O2 Batteries 179
11.5.6 Aqueous Zinc-Ion Rechargeable Batteries 180
11.5.6.1 Insertion/Extraction Mechanism 180
11.5.6.2 Chemical Conversion Mechanism 180
11.5.6.3 H+ and Zn2+ Insertion/Extraction Mechanism 181
11.6 Future Perspectives 181
11.7 Conclusion 182
Abbreviations 182
Acknowledgement 183
References 183
12 Electrolytes for Zinc-Air Batteries 187
Zahra Farmani, Mohammad Amin Sedghamiz,
and Mohammad Reza Rahimpour
12.1 Introduction 187
12.2 Aqueous Electrolytes 188
12.2.1 Alkaline Electrolytes 189
12.2.1.1 Dissolution of Zinc in Alkaline Systems 189
12.2.1.2 Insoluble Carbonates Precipitation 192
12.2.1.3 Effect of Water 193
12.2.1.4 Hydrogen Evolution 194
12.2.2 Neutral Electrolytes 195
12.2.3 Acidic Electrolytes 196
12.3 Electrolytes of Non-Aqueous 197
12.3.1 Non-Aqueous Electrolytes 199
12.3 Summary 203
References 206
13 Safety and Environmental Impact of Zinc Battery 215
ManjuYadav and Dinesh Kumar
13.1 Introduction 215
13.2 Security of Zinc Battery 217
13.2.1 Modifications for Improving Performance 218
13.2.1.1 High Surface Area 218
13.2.1.2 Carbon-Based Electrode Additives 221
13.2.1.3 Discharge-Capturing Electrode
Additives 221
13.2.1.4 Electrode Coatings 222
13.2.1.5 Electrolyte Additives 222
13.2.1.6 Heavy-Metals Electrode Additive 222
13.2.1.7 Polymeric Binders 223
13.2.2 Storage and Handling 224
13.3 Influence of Zinc Battery 224
13.3.1 Consumption of Natural Resources 225
13.3.2 Toxicity of Batteries to Humans 226
13.3.3 Toxicity of Batteries to the Aquatic Environment 226
13.4 Disposal/Recycling Options 227
Acknowledgement 228
References 228
14 Materials for Ni-Zn Batteries 235
Vaishali Tomar and Dinesh Kumar
14.1 Introduction 235
14.1.1 Functioning Principles of Nickel-Zinc Battery 237
14.1.2 Ni-Zn Battery Design 238
14.2 Expansion of Ni-Zn Battery 239
14.2.1 Active Materials for the Battery 240
14.3 Application 241
14.4 Conclusion 242
Acknowledgement 243
References 243
Index 249
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BISAC SUBJECT HEADINGS
TEC031010: TECHNOLOGY & ENGINEERING / Power Resources / Alternative & Renewable
SCI024000: SCIENCE / Energy
BUS070040: BUSINESS & ECONOMICS / Industries / Energy
BIC CODES
THRH: Energy conversion and storage
TDCB: Chemical engineering
TGM : Materials science
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