Electrochemical Energy Storage Technologies Beyond Li-ion Batteries: Fundamentals, Materials, Devices
Editat de Guanjie Heen Limba Engleză Paperback – 3 dec 2024
- Provides a thorough overview of candidate materials for electrochemical energy storage technologies, including batteries, fuel cells, and supercapacitors
- Summarizes fundamental principles of electrochemical energy storage such as energy storage mechanisms, device design considerations, and computational and characterization methods
- Discusses future opportunities and challenges of recycling of electrochemical energy storage technologies and non-lithium energy storage
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Specificații
ISBN-13: 9780443155147
ISBN-10: 0443155143
Pagini: 602
Dimensiuni: 152 x 229 mm
Greutate: 0.45 kg
Editura: ELSEVIER SCIENCE
ISBN-10: 0443155143
Pagini: 602
Dimensiuni: 152 x 229 mm
Greutate: 0.45 kg
Editura: ELSEVIER SCIENCE
Cuprins
PART 1 Fundamentals of electrochemical energy storage technologies
1. Fundamental electrochemical energy storage mechanisms
1 Overview
2 Electron transfer and mass transport
3 Electrochemistry of electrolyte
4 Electrochemistry of electrode
5 Interface
2. Configurations of electrochemical energy storage devices
1 Overview
2 Device configuration design principles
3 Redox flow batteries (RFBs)
4 The function of separators
3. Material characterization and electrochemical test
techniques
1 Introduction
2 Basic characterization and electrochemical test techniques
3 Advanced characterization and electrochemical test techniques
4 Conclusion
4. Selected quantum chemical studies on the surfaces and interfaces of carbon materials for applications in lithium-ion
batteries and beyond
1 Introduction
2 A brief introduction to density functional theory (DFT)
3 The interaction of Li, Na, and K with carbon materials
4 Concluding remarks and perspectives
PART 2 Non-lithium-ion rocking chair batteries: Candidate materials and device design considerations
5. Sodium-ion batteries
1 Introduction
2 Anode materials
3 Electrolytes for NIBs
4 Separators and current collectors for NIBs
5 Cathode materials
6 Conclusions
6. Potassium-ion batteries: Mechanism, design,
and perspectives
1 Introduction
2 Anode materials
3 Cathode materials
4 Electrolytes
5 Binders
6 Conclusion and perspectives
7. Zinc-ion batteries: Recent trends in zinc-ion batteries
1 Introduction
2 Materials used in zinc-ion batteries
8. Rechargeable magnesium-ion batteries: From mechanism
to emerging materials
1 Introduction
2 Working mechanism and main challenges
3 Cathode
4 Anode
5 Electrolyte
6 Summary and outlooks
9. Aluminum-ion batteries
1 Introduction of rechargeable aluminum-ion batteries
2 Cathode materials
3 Electrolytes
4 Al metal anode and related technologies
5 Other materials
6 Conclusion and perspectives
10. Calcium-ion batteries
1 A general introduction to this technology
2 Challenges in developing modern CIBs
3 Anode materials
4 Cathode
5 Perspectives
11. Materials electrochemistry for dual-ion batteries
1 Understanding of dual-ion batteries
2 Positive electrode design
3 Negative electrode design
4 Electrolyte design
5 Conclusion and perspectives
PART 3 Emerging metal-air batteries and fuel cells: Candidate materials and device design considerations
12. Lithium-air batteries
1 Introduction
2 Anode materials
3 Air-cathode materials
4 Electrolytes
5 Other components
6 Conclusion and future perspectives
13. Zinc-air batteries
1 A general introduction to this technology
2 Zn anode-related technologies
3 Air-cathode materials
4 Electrolytes
5 Other components (binder, current collector, separator, etc.)
6 Conclusion and perspectives
14. Solid oxide fuel cells (SOFCs)
1 Introduction
2 Electrolyte materials
3 SOFC electrode materials
4 Other components (interconnect)
5 Electrocatalysts
6 Commercialization and industrialization of SOFCs
7 Conclusions
PART 4 Redox flow batteries: Candidate materials and device design considerations
15. All-vanadium redox flow batteries
1 Topic 1: A general introduction to this technology
2 Topic 2: Electrolyte materials
3 Topic 3: Membrane materials
4 Topic 4: Electrodes
5 Topic 5 Summary and perspective
16. Zinc-based hybrid flow batteries
1 Overview
2 Introduction
3 Different types and configurations of ZHFBs
4 Other components of ZHFBs
5 Conclusions and outlook
PART 5 Supercapacitors: Candidate materials and device design considerations
17. Electrochemical double layer capacitors (EDLCs)
1 Electric double layer (EDL)
2 Application of double electric layer
18. Pseudocapacitors
1 Overview
2 Pseudocapacitive energy storage mechanisms
3 Kinetic analysis
4 Device structure
5 Performance evaluation
6 Pseudocapacitive materials
7 Pseudocapacitive electrolytes
8 Conclusion and perspectives
19. Exploring hybrid capacitors: Advanced concepts and applications
1 Introduction
2 Different HCs and the anode and cathode materials
3 Electrolytes
4 Binders
5 Separator
6 Current collector
7 Conclusion
PART 6 Future outlooks and challenges
20. Challenges and future prospective of nonlithium electrochemical energy storage technologies
1 Overview
2 Challenges in practical application of nonlithium technologies
3 Strategies for overcoming challenges
4 Future prospects and market dynamics
1. Fundamental electrochemical energy storage mechanisms
1 Overview
2 Electron transfer and mass transport
3 Electrochemistry of electrolyte
4 Electrochemistry of electrode
5 Interface
2. Configurations of electrochemical energy storage devices
1 Overview
2 Device configuration design principles
3 Redox flow batteries (RFBs)
4 The function of separators
3. Material characterization and electrochemical test
techniques
1 Introduction
2 Basic characterization and electrochemical test techniques
3 Advanced characterization and electrochemical test techniques
4 Conclusion
4. Selected quantum chemical studies on the surfaces and interfaces of carbon materials for applications in lithium-ion
batteries and beyond
1 Introduction
2 A brief introduction to density functional theory (DFT)
3 The interaction of Li, Na, and K with carbon materials
4 Concluding remarks and perspectives
PART 2 Non-lithium-ion rocking chair batteries: Candidate materials and device design considerations
5. Sodium-ion batteries
1 Introduction
2 Anode materials
3 Electrolytes for NIBs
4 Separators and current collectors for NIBs
5 Cathode materials
6 Conclusions
6. Potassium-ion batteries: Mechanism, design,
and perspectives
1 Introduction
2 Anode materials
3 Cathode materials
4 Electrolytes
5 Binders
6 Conclusion and perspectives
7. Zinc-ion batteries: Recent trends in zinc-ion batteries
1 Introduction
2 Materials used in zinc-ion batteries
8. Rechargeable magnesium-ion batteries: From mechanism
to emerging materials
1 Introduction
2 Working mechanism and main challenges
3 Cathode
4 Anode
5 Electrolyte
6 Summary and outlooks
9. Aluminum-ion batteries
1 Introduction of rechargeable aluminum-ion batteries
2 Cathode materials
3 Electrolytes
4 Al metal anode and related technologies
5 Other materials
6 Conclusion and perspectives
10. Calcium-ion batteries
1 A general introduction to this technology
2 Challenges in developing modern CIBs
3 Anode materials
4 Cathode
5 Perspectives
11. Materials electrochemistry for dual-ion batteries
1 Understanding of dual-ion batteries
2 Positive electrode design
3 Negative electrode design
4 Electrolyte design
5 Conclusion and perspectives
PART 3 Emerging metal-air batteries and fuel cells: Candidate materials and device design considerations
12. Lithium-air batteries
1 Introduction
2 Anode materials
3 Air-cathode materials
4 Electrolytes
5 Other components
6 Conclusion and future perspectives
13. Zinc-air batteries
1 A general introduction to this technology
2 Zn anode-related technologies
3 Air-cathode materials
4 Electrolytes
5 Other components (binder, current collector, separator, etc.)
6 Conclusion and perspectives
14. Solid oxide fuel cells (SOFCs)
1 Introduction
2 Electrolyte materials
3 SOFC electrode materials
4 Other components (interconnect)
5 Electrocatalysts
6 Commercialization and industrialization of SOFCs
7 Conclusions
PART 4 Redox flow batteries: Candidate materials and device design considerations
15. All-vanadium redox flow batteries
1 Topic 1: A general introduction to this technology
2 Topic 2: Electrolyte materials
3 Topic 3: Membrane materials
4 Topic 4: Electrodes
5 Topic 5 Summary and perspective
16. Zinc-based hybrid flow batteries
1 Overview
2 Introduction
3 Different types and configurations of ZHFBs
4 Other components of ZHFBs
5 Conclusions and outlook
PART 5 Supercapacitors: Candidate materials and device design considerations
17. Electrochemical double layer capacitors (EDLCs)
1 Electric double layer (EDL)
2 Application of double electric layer
18. Pseudocapacitors
1 Overview
2 Pseudocapacitive energy storage mechanisms
3 Kinetic analysis
4 Device structure
5 Performance evaluation
6 Pseudocapacitive materials
7 Pseudocapacitive electrolytes
8 Conclusion and perspectives
19. Exploring hybrid capacitors: Advanced concepts and applications
1 Introduction
2 Different HCs and the anode and cathode materials
3 Electrolytes
4 Binders
5 Separator
6 Current collector
7 Conclusion
PART 6 Future outlooks and challenges
20. Challenges and future prospective of nonlithium electrochemical energy storage technologies
1 Overview
2 Challenges in practical application of nonlithium technologies
3 Strategies for overcoming challenges
4 Future prospects and market dynamics