Advances in batteries for large- and medium-scale energy storage :
[Book]
applications in power systems and electric vehicles
by C. Menictas.
Oxford
Woodhead Publishing
2014
pages cm.
Woodhead Publishing series in energy
List of contributorsWoodhead Publishing Series in EnergyPart One: IntroductionChapter 1: Electrochemical cells for medium- and large-scale energy storage: fundamentalsAbstract1.1 Introduction1.2 Potential and capacity of an electrochemical cell1.3 Electrochemical fundamentals in practical electrochemical cellsChapter 2: Economics of batteries for medium- and large-scale energy storageAbstract2.1 Introduction2.2 Small-scale project2.3 Large-scale project2.4 ConclusionsPart Two: Lead, nickel, sodium, and lithium-based batteriesChapter 3: Lead-acid batteries for medium- and large-scale energy storageAbstract3.1 Introduction3.2 Electrochemistry of the lead-acid battery3.3 Pb-acid battery designs3.4 Aging effects and failure mechanisms3.5 Advanced lead-acid batteries3.6 Applications of lead-acid batteries in medium- and long-term energy storage3.7 Summary and future trendsChapter 4: Nickel-based batteries for medium- and large-scale energy storageAbstract4.1 Introduction4.2 Basic battery chemistry4.3 Battery development and applications4.4 Future trends4.5 Sources of further information and adviceChapter 5: Molten salt batteries for medium- and large-scale energy storageAbstract5.1 Introduction5.2 Sodium- -alumina batteries (NBBs)5.3 Challenges and future trendsChapter 6: Lithium-ion batteries (LIBs) for medium- and large-scale energy storage: current cell materials and componentsAbstract6.1 Introduction6.2 Chemistry of lithium-ion batteries: anodes6.3 Chemistry of LIBs: cathodes6.4 Chemistry of LIBs: electrolytes6.5 Chemistry of LIBs: inert components6.6 Lithium-aluminum/iron-sulfide (LiAl-FeS(2)) batteries6.7 Sources of further information and adviceChapter 7: Lithium-ion batteries (LIBs) for medium- and large-scale energy storage: emerging cell materials and componentsAbstract7.1 Introduction7.2 Anodes7.3 Cathodes7.4 Electrolytes7.5 Inert components7.6 Sources of further information and advicePart Three: Other types of batteriesChapter 8: Zinc-based flow batteries for medium- and large-scale energy storageAbstract8.1 Introduction8.2 Zinc-bromine flow batteries8.3 Zinc-cerium flow batteries8.4 Zinc-air flow batteries8.5 Other zinc-based flow batteriesChapter 9: Polysulfide-bromine flow batteries (PBBs) for medium- and large-scale energy storageAbstract9.1 Introduction9.2 PBBs: principles and technologies9.3 Electrolyte solution and its chemistry9.4 Electrode materials9.5 Ion-conductive membrane separators for PBBs9.6 PBB applications and performance9.7 Summary and future trendsChapter 10: Vanadium redox flow batteries (VRBs) for medium- and large-scale energy storageAbstract10.1 Introduction10.2 Cell reactions, general features, and operating principles10.3 Cell materials10.4 Electrolyte preparation and optimization10.5 Cell and battery performance10.6 State-of-charge (SOC) monitoring and flow rate control10.7 Field trials, demonstrations, and commercialization10.8 Other VRB chemistries10.9 Modeling and simulations10.10 Cost considerations10.11 ConclusionsChapter 11: Lithium-air batteries for medium- and large-scale energy storageAbstract11.1 Introduction11.2 Lithium ion batteries11.3 Lithium oxygen battery11.4 Li-SES anode11.5 LiPON thin film and its application to the Li battery11.6 Carbon materials as cathode in Li-O2 battery11.7 Fluorinated ether as an additive for the lithium oxygen battery11.8 SummaryNotesChapter 12: Zinc-air and other types of metal-air batteriesAbstract12.1 Introduction12.2 Challenges in zinc-air cell chemistry12.3 Advances in zinc-air batteries12.4 Future trends in zinc-air batteries12.5 Other metal-air batteriesChapter 13: Aluminum-ion batteries for medium- and large-scale energy storageAbstractAcknowledgments13.1 Introduction13.2 Al-ion battery chemistry13.3 ConclusionsPart Four: Design issues and applicationsChapter 14: Advances in membrane and stack design of redox flow batteries (RFBs) for medium- and large-scale energy storageAbstract14.1 Introduction14.2 Membranes used in redox flow batteries14.3 Membrane evaluation in vanadium redox flow batteries14.4 Research and development on membranes for redox flow battery applications14.5 Chemical stability of membranes14.6 ConclusionChapter 15: Modeling the design of batteries for medium- and large-scale energy storageAbstract15.1 Introduction15.2 The main components of lithium-ion batteries (LIBs)15.3 The use of density functional theory (DFT) to analyze LIB materials15.4 Structure-property relationships of electrode materials15.5 Structure-property relationships of polyanionic compounds used in LIBs15.6 Analyzing electron density and structure modification in LIB materials15.7 Structure-property relationships in organic-based electrode materials for LIBs15.8 Modeling specific power and rate capability: ionic and electronic conductivity15.9 Modeling intercalation or conversion reactions in LIB materials15.10 Modeling solid-electrolyte interphase (SEI) formation15.11 Modeling microstructural properties in LIB materials15.12 Modeling thermomechanical stresses in LIB materials15.13 Multiscale modeling of LIB performance15.14 Modeling emerging battery technologies: lithium-air batteries (LABs), all solid-state LIBs, and redox flow batteries15.15 ConclusionsChapter 16: Batteries for remote area power (RAP) supply systemsAbstract16.1 Introduction16.2 Components of a RAPS system16.3 Existing battery systems for RAPS16.4 Future considerations16.5 Concluding remarksChapter 17: Applications of batteries for grid-scale energy storageAbstract17.1 Introduction17.2 Storage and electricity grids17.3 The need for storage17.4 Battery technologies17.5 The effect of battery storage on the system17.6 Location of storage17.7 Regulatory and economic issues17.8 Sources of further information and adviceIndex