UID:
almahu_9949464775202882
Format:
1 online resource (765 p.)
ISBN:
9781000626018
,
1000626016
,
9781003308744
,
1003308740
,
1000625931
,
9781000625936
Content:
The need for batteries has grown exponentially in response to the increase in global energy demand and to the ambitious goals that governments have set up for sustainable energy development worldwide, especially in developed countries. While lithium-ion batteries currently dominate the energy storage market, the limited and unevenly distributed lithium resources have caused huge concerns over the sustainability of the lithium-ion battery technology. Sodium-ion batteries have significant benefits over lithium-ion batteries, including sodium's abundance in the Earth's crust. These batteries have therefore gained research interest, and efforts are being made to use them in place of lithium-ion batteries. While the past decade has witnessed significant research advances and breakthroughs in developing the sodium-ion battery technology, there still remain fundamental challenges that must be overcome to push the technology forward. This book comprises 13 chapters that discuss the fundamental challenges, electrode materials, electrolytes, separators, advanced instrumental analysis techniques, and computational methods for sodium-ion batteries from renowned scientists. The book is a unique combination of all aspects associated with sodium-ion batteries and can therefore be used as a handbook.
Note:
Description based upon print version of record.
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4.4.4: Other Prussian Blue Analog Compounds
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Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- Preface -- Chapter 1: Challenges and Opportunities in Sodium-Ion Batteries: An Introduction -- 1.1: Importance of Batteries for Energy Storage -- 1.2: Developing Sodium-Ion Battery -- 1.3: Anodes -- 1.3.1: Carbon-Based Anodes -- 1.3.2: Carbon Alloy-Based Anodes -- 1.3.3: Other Anode Materials -- 1.4: Cathodes -- 1.4.1: Fluoride-Based Cathodes -- 1.4.2: Prussian Blue Analogues -- 1.4.3: Other Cathode Materials -- 1.5: Electrolytes -- 1.6: Summary and Future Perspective -- Chapter 2: Principles of Electrochemistry
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2.1: Electrochemical Cells -- 2.2: Alkali-Ion Batteries -- 2.3: Thermodynamics -- 2.4: Electrode Reaction Kinetics -- 2.5: Electrode Reaction Mechanisms -- Chapter 3: Cathode Materials for Sodium-Ion Batteries -- 3.1: Introduction -- 3.2: Sodium Layered Oxides -- 3.2.1: Structure and Properties of Layered Transition Metal Oxides -- 3.2.2: NaxCoO2 and Its Derivatives -- 3.2.3: NaxMnO2 and Its Derivatives -- 3.2.4: NaxFeO2 and Its Derivatives -- 3.2.5: NaNiO2 and Its Derivatives -- 3.2.6: NiCrO2 and Its Derivatives -- 3.2.7: NiVO2 and Its Derivatives -- 3.2.8: Other NaxMO2
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3.3: Polyanionic Materials -- 3.3.1: Phosphates -- 3.3.1.1: Olivine -- 3.3.1.2: NASICON -- 3.3.1.3: Pyrophosphates -- 3.3.1.4: Fluorophosphates -- 3.3.1.5: Other phosphates -- 3.3.2: Sulfates -- 3.3.2.1: Fluorosulfates -- 3.3.2.2: Alluaudites -- 3.3.3: Other Oxysalts -- 3.3.3.1: Silicates -- 3.3.3.2: Carbonophosphates -- 3.4: Prussian Blue Analogs -- 3.4.1: Crystal Structure of Prussian Blue Analogs -- 3.4.2: Iron Hexacyanoferrate -- 3.4.3: Manganese Hexacyanoferrate -- 3.4.4: Cobalt Hexacyanoferrate -- 3.4.5: Nickel Hexacyanoferrate -- 3.4.6: Other Hexacyanoferrate Compounds
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3.4.7: Structural and Morphological Optimizations of PBAs -- 3.5: Conversion-Based Cathode Materials -- 3.5.1: Metal Fluorides -- 3.5.2: Carbon Fluorides -- 3.5.3: Oxyfluorides -- 3.5.4: Metal Sulfides -- 3.5.5: Metal Selenides -- 3.5.6: Other Conversion Cathode Materials -- 3.6: Organic Cathode Materials -- 3.6.1: Carbonyl Compounds (C=O Reaction) -- 3.6.1.1: Quinones and ketones -- 3.6.1.2: Anhydrides and imides -- 3.6.2: Pteridine Derivatives (C=N Reaction) -- 3.6.3: Polymers (Doping Reaction) -- 3.6.3.1: Conductive polymers -- 3.6.3.2: Nitroxyl radical polymer -- 3.6.3.3: Microporous polymers
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3.6.3.4: Organometallic polymers -- 3.7 Conclusion -- Chapter 4: Prussian Blue Analogues as Cathode Materials for Sodium-Ion Batteries -- 4.1: Introduction -- 4.2: Structure and Working Principle of PBAs -- 4.2.1: Typical Structures and Phases of PBAs -- 4.2.2: Redox Reaction and Electric Energy Storage Mechanism -- 4.2.3: Na+ Diffusion -- 4.2.4: Phase Transition During Charge/Discharge -- 4.3: Synthesis Methods -- 4.4: Typical Hexacyanoferrate -- 4.4.1: Nickel Hexacyanoferrate (NiHCF) -- 4.4.2: Iron Hexacyanoferrate (FeHCF) -- 4.4.3: Manganese Hexacyanoferrate (MnHCF)
Additional Edition:
Print version: Zhao, George Handbook of Sodium-Ion Batteries Milton : Jenny Stanford Publishing,c2023 ISBN 9789814968157
Language:
English
DOI:
10.1201/9781003308744
URL:
https://www.taylorfrancis.com/books/9781003308744
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