Advances in Batteries for Medium and Large-Scale Energy Storage

Chris Menictas, School of Mechanical and Manufacturing Engineering, The University of New South Wales, Australia Maria Skyllas-Kazacos University of New South Wales, Australia. Lim Tuti Mariana, Nanyang Technological University, Singapore.

List of contributors
Woodhead Publishing Series in Energy

Part One: Introduction
1: Electrochemical cells for medium- and large-scale energy storage: fundamentals
Abstract
1.1 Introduction
1.2 Potential and capacity of an electrochemical cell
1.3 Electrochemical fundamentals in practical electrochemical cells
Chapter 2: Economics of batteries for medium- and large-scale energy storage
Abstract
2.1 Introduction
2.2 Small-scale project
2.3 Large-scale project
2.4 Conclusions

Part Two: Lead, nickel, sodium, and lithium-based batteries
3: Lead-acid batteries for medium- and large-scale energy storage
Abstract
3.1 Introduction
3.2 Electrochemistry of the lead-acid battery
3.3 Pb-acid battery designs
3.4 Aging effects and failure mechanisms
3.5 Advanced lead-acid batteries
3.6 Applications of lead-acid batteries in medium- and long-term energy storage
3.7 Summary and future trends
4: Nickel-based batteries for medium- and large-scale energy storage
Abstract
4.1 Introduction
4.2 Basic battery chemistry
4.3 Battery development and applications
4.4 Future trends
4.5 Sources of further information and advice
5: Molten salt batteries for medium- and large-scale energy storage
Abstract
5.1 Introduction
5.2 Sodium-ß-alumina batteries (NBBs)
5.3 Challenges and future trends
6: Lithium-ion batteries (LIBs) for medium- and large-scale energy storage: current cell materials and components
Abstract
6.1 Introduction
6.2 Chemistry of lithium-ion batteries: anodes
6.3 Chemistry of LIBs: cathodes
6.4 Chemistry of LIBs: electrolytes
6.5 Chemistry of LIBs: inert components
6.6 Lithium-aluminum/iron-sulfide (LiAl-FeS(2)) batteries
6.7 Sources of further information and advice
7: Lithium-ion batteries (LIBs) for medium- and large-scale energy storage: emerging cell materials and components
Abstract
7.1 Introduction
7.2 Anodes
7.3 Cathodes
7.4 Electrolytes
7.5 Inert components
7.6 Sources of further information and advice

Part Three: Other types of batteries
8: Zinc-based flow batteries for medium- and large-scale energy storage
Abstract
8.1 Introduction
8.2 Zinc-bromine flow batteries
8.3 Zinc-cerium flow batteries
8.4 Zinc-air flow batteries
8.5 Other zinc-based flow batteries
9: Polysulfide-bromine flow batteries (PBBs) for medium- and large-scale energy storage
Abstract
9.1 Introduction
9.2 PBBs: principles and technologies
9.3 Electrolyte solution and its chemistry
9.4 Electrode materials
9.5 Ion-conductive membrane separators for PBBs
9.6 PBB applications and performance
9.7 Summary and future trends
10: Vanadium redox flow batteries (VRBs) for medium- and large-scale energy storage
Abstract
10.1 Introduction
10.2 Cell reactions, general features, and operating principles
10.3 Cell materials
10.4 Electrolyte preparation and optimization
10.5 Cell and battery performance
10.6 State-of-charge (SOC) monitoring and flow rate control
10.7 Field trials, demonstrations, and commercialization
10.8 Other VRB chemistries
10.9 Modeling and simulations
10.10 Cost considerations
10.11 Conclusions
11: Lithium-air batteries for medium- and large-scale energy storage
Abstract
11.1 Introduction
11.2 Lithium ion batteries
11.3 Lithium oxygen battery
11.4 Li-SES anode
11.5 LiPON thin film and its application to the Li battery
11.6 Carbon materials as cathode in Li-O2 battery
11.7 Fluorinated ether as an additive for the lithium oxygen battery
11.8 Summary
Notes
12: Zinc-air and other types of metal-air batteries
Abstract
12.1 Introduction
12.2 Challenges in zinc-air cell chemistry
12.3 Advances in zinc-air batteries
12.4 Future trends in zinc-air batteries
12.5 Other metal-air batteries
13: Aluminum-ion batteries for medium- and large-scale energy storage
Abstract
Acknowledgments
13.1 Introduction
13.2 Al-ion battery chemistry
13.3 Conclusions

Part Four: Design issues and applications
14: Advances in membrane and stack design of redox flow batteries (RFBs) for medium- and large-scale energy storage
Abstract
14.1 Introduction
14.2 Membranes used in redox flow batteries
14.3 Membrane evaluation in vanadium redox flow batteries
14.4 Research and development on membranes for redox flow battery applications
14.5 Chemical stability of membranes
14.6 Conclusion
15: Modeling the design of batteries for medium- and large-scale energy storage
Abstract
15.1 Introduction
15.2 The main components of lithium-ion batteries (LIBs)
15.3 The use of density functional theory (DFT) to analyze LIB materials
15.4 Structure–property relationships of electrode materials
15.5 Structure–property relationships of polyanionic compounds used in LIBs
15.6 Analyzing electron density and structure modification in LIB materials
15.7 Structure–property relationships in organic-based electrode materials for LIBs
15.8 Modeling specific power and rate capability: ionic and electronic conductivity
15.9 Modeling intercalation or conversion reactions in LIB materials
15.10 Modeling solid-electrolyte interphase (SEI) formation
15.11 Modeling microstructural properties in LIB materials
15.12 Modeling thermomechanical stresses in LIB materials
15.13 Multiscale modeling of LIB performance
15.14 Modeling emerging battery technologies: lithium-air batteries (LABs), all solid-state LIBs, and redox flow batteries
15.15 Conclusions
16: Batteries for remote area power (RAP) supply systems
Abstract
16.1 Introduction
16.2 Components of a RAPS system
16.3 Existing battery systems for RAPS
16.4 Future considerations
16.5 Concluding remarks
17: Applications of batteries for grid-scale energy storage
Abstract
17.1 Introduction
17.2 Storage and electricity grids
17.3 The need for storage
17.4 Battery technologies
17.5 The effect of battery storage on the system
17.6 Location of storage
17.7 Regulatory and economic issues
17.8 Sources of further information and advice
Index