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Supercapacitors Based on Carbon or Pseudocapacitive Materials.

By: Contributor(s): Material type: TextTextPublisher: Newark : John Wiley & Sons, Incorporated, 2017Copyright date: ©2017Edition: 1st edDescription: 1 online resource (134 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781119007340
Subject(s): Genre/Form: Additional physical formats: Print version:: Supercapacitors Based on Carbon or Pseudocapacitive MaterialsDDC classification:
  • 621.31500000000005
LOC classification:
  • TK7872.C65.S566 2017
Online resources:
Contents:
Cover -- Half-Title Page -- Title Page -- Copyright -- Contents -- Introduction -- I.1. Why supercapacitors? -- I.2. Some figures -- I.3. Applications -- I.4. The key parameters of supercapacitors -- I.4.1. Cell voltage V -- I.4.2. Capacitance -- I.4.3. Series resistance R -- I.4.4. Energy -- I.4.5. Power -- I.5. Carbon-based supercapacitors (EDLCs) -- I.5.1. Charge storage in EDLCs -- I.5.2. Electrochemical characteristics of EDLCs -- I.6. Challenges for supercapacitors -- I.6.1. Increasing the capacitance of EDLCs -- I.6.2. Increasing the cell voltage -- I.6.3. Increasing the capacitance: pseudocapacitive materials -- I.6.4. Hybrid devices -- 1. Electrochemical Double-Layer Capacitors (EDLC) -- 1.1. The different forms of carbon -- 1.2. Increasing the capacitance of microporous carbon -- 1.3. Activated microporous carbon -- 1.4. Hierarchical porous carbon -- 1.5 Graphene -- 1.6. Reducing costs: carbons in aqueous media -- 1.7. Functionalized carbon -- 1.8. Conclusion -- 2. Electrolytes -- 2.1. High potential electrolytes -- 2.2. What about AN? -- 2.3. Conclusion -- 3. Pseudocapacitive Materials -- 3.1. Conductive polymers -- 3.2. Metal oxides -- 3.3. Transition metal nitrides -- 3.4. Conclusion -- 4. Hybrid and/or Asymmetric Systems -- 4.1. Hybrid devices (asymmetric) in aqueous electrolytes -- 4.1.1. Concept and limitations -- 4.1.2. Activated carbon/PbO2 device -- 4.1.3. Hybrid AC/Ni(OH)2 device -- 4.2. Asymmetric aqueous supercapacitors -- 4.2.1. Activated carbon/MnO2 devices -- 4.2.2. Asymmetric carbon/carbon devices -- 4.2.3. Conclusions on hybrid systems in aqueous electrolytes -- 4.3. Hybrid devices in organic electrolytes -- 4.3.1. Hybrid titanate/activated carbon systems -- 4.3.2. Hybrid graphite/activated carbon systems -- 4.4. Conclusion -- Conclusion -- Bibliography -- Index -- Other titles from iSTE in Energy -- EULA.
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Cover -- Half-Title Page -- Title Page -- Copyright -- Contents -- Introduction -- I.1. Why supercapacitors? -- I.2. Some figures -- I.3. Applications -- I.4. The key parameters of supercapacitors -- I.4.1. Cell voltage V -- I.4.2. Capacitance -- I.4.3. Series resistance R -- I.4.4. Energy -- I.4.5. Power -- I.5. Carbon-based supercapacitors (EDLCs) -- I.5.1. Charge storage in EDLCs -- I.5.2. Electrochemical characteristics of EDLCs -- I.6. Challenges for supercapacitors -- I.6.1. Increasing the capacitance of EDLCs -- I.6.2. Increasing the cell voltage -- I.6.3. Increasing the capacitance: pseudocapacitive materials -- I.6.4. Hybrid devices -- 1. Electrochemical Double-Layer Capacitors (EDLC) -- 1.1. The different forms of carbon -- 1.2. Increasing the capacitance of microporous carbon -- 1.3. Activated microporous carbon -- 1.4. Hierarchical porous carbon -- 1.5 Graphene -- 1.6. Reducing costs: carbons in aqueous media -- 1.7. Functionalized carbon -- 1.8. Conclusion -- 2. Electrolytes -- 2.1. High potential electrolytes -- 2.2. What about AN? -- 2.3. Conclusion -- 3. Pseudocapacitive Materials -- 3.1. Conductive polymers -- 3.2. Metal oxides -- 3.3. Transition metal nitrides -- 3.4. Conclusion -- 4. Hybrid and/or Asymmetric Systems -- 4.1. Hybrid devices (asymmetric) in aqueous electrolytes -- 4.1.1. Concept and limitations -- 4.1.2. Activated carbon/PbO2 device -- 4.1.3. Hybrid AC/Ni(OH)2 device -- 4.2. Asymmetric aqueous supercapacitors -- 4.2.1. Activated carbon/MnO2 devices -- 4.2.2. Asymmetric carbon/carbon devices -- 4.2.3. Conclusions on hybrid systems in aqueous electrolytes -- 4.3. Hybrid devices in organic electrolytes -- 4.3.1. Hybrid titanate/activated carbon systems -- 4.3.2. Hybrid graphite/activated carbon systems -- 4.4. Conclusion -- Conclusion -- Bibliography -- Index -- Other titles from iSTE in Energy -- EULA.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.

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