Electrochemical energy conversion and storage / Yuping Wu and Rudolf Holze.

Format:

Book

Author/Creator:

Holze, R. (Rudolf), 1954- author.

Wu, Yuping, 1969- author.

Contributor:

Alumni and Friends Memorial Book Fund.

Language:

English

Subjects (All):

Electrochemistry.

Energy conversion.

Energy storage.

Medical Subjects:

Electrochemistry.

Physical Description:

xiv, 415 pages : illustrations ; 25 cm

Place of Publication:

Weinheim, Germany : Wiley-VCH, [2022]

Contents:

Machine generated contents note: 1. Processes and Applications of Energy Conversion and Storage

2. Electrochemical Processes and Systems

2.1. Parasitic Reactions

2.2. Self-discharge

2.3. Device Deterioration

2.3.1. Aging

3. Thermodynamics of Electrochemical Systems

4. Kinetics of Electrochemical Energy Conversion Processes

4.1. Steps of Electrode Reactions and Overpotentials

4.2. Transport

4.3. Charge Transfer

4.4. Overpotentials

4.5. Diffusion

4.6. Further Overpotentials

5. Electrodes and Electrolytes

5.1. Recycling

6. Experimental Methods

6.1. Battery Tester

6.2. Current-Potential Measurements

6.3. Charge/Discharge Measurements

6.4. Battery Charging

6.5. Linear Scan and Cyclic Voltammetry

6.6. Impedance Measurements

6.7. Galvanostatic Intermittent Titration Technique (GITT)

6.8. Potentiostatic Intermittent Titration Technique (PITT)

6.9. Step Potential Electrochemical Spectroscopy (SPECS)

6.10. Electrochemical Quartz Crystal Microbalance (EQCM)

6.11. Non-electrochemical Methods

6.11.1. Solid-state Nuclear Magnetic Resonance

6.11.2. Gas Adsorption Measurements

6.11.3. Microscopies

6.11.4. Thermal Measurements

6.11.5. Modeling

7. Primary Systems

7.1. Aqueous Systems

7.1.1. Zinc-Carbon Battery

7.1.2. Alkaline Zn//MnO2 Battery

7.1.3. Zn//HgO Battery

7.1.4. Zn//AgO Battery

7.1.5. Cd//AgO Batteries

7.1.6. Mg//MnO2 Batteries

7.2. Nonaqueous Systems

7.2.1. Primary Lithium Batteries

7.2.2. Li//MnO2

7.2.3. Li//Bi2O3

7.2.4. Li//CuO

7.2.5. Li//V2O5, Li//Ag2V4Ou, and Li//CSVO

7.2.6. Li//CuS

7.2.7. Li//FeS2

7.2.8. Li//CFX Primary Battery

7.2.9. Li//I2

7.2.10. Li//SO2

7.2.11. Li//SOCl2

7.2.12. Li//SO2Cl2

7.2.13. Li//Oxyhalide Primary Battery

7.3. Metal-Air Systems

7.3.1. Aqueous Metal-Air Primary Batteries

7.3.2. Nonaqueous Metal-Air Batteries

7.4. Reserve Batteries

7.4.1. Seawater-activated Batteries

7.4.2. High Power Activated Batteries

8. Secondary Systems

8.1. Aqueous Systems

8.1.1. Lead-Acid

8.1.2. Lead Grid

8.1.3. Ni-based Secondary Batteries

8.1.4. Aqueous Rechargeable Lithium Batteries

8.1.5. Aqueous Rechargeable Sodium Batteries

8.2. Nonaqueous Systems

8.2.1. Lithium-Ion Batteries

8.2.2. Rechargeable Li//S Batteries

8.2.3. Rechargeable Na//S Batteries

8.2.4. Rechargeable Li//Se Batteries

8.2.5. Rechargeable Mg Batteries

8.3. Gel Polymer Electrolyte-based Secondary Batteries

8.3.1. Gel Lithium-Ion Batteries

8.3.2. Gel-Type Electrolytes for Sodium Batteries

8.4. Solid Electrolyte-based Secondary Batteries

8.4.1. Solid Lithium-Ion Batteries

8.4.2. Rechargeable Solid Lithium Batteries

8.5. Rechargeable Metal-Air Batteries

8.5.1. Rechargeable Li//Air Batteries

8.5.2. Rechargeable Na//Air Batteries

8.5.3. Rechargeable Zn//Air Batteries

8.6. High-Temperature Systems

8.6.1. Sodium-Sulfur Battery

8.6.2. Sodium-Nickel Chloride Battery

8.6.3. All Liquid Metal Accumalator

9. Fuel Cells

9.1. The Oxygen Electrode

9.2. The Hydrogen Electrode

9.3. Common Features of Fuel Cells

9.4. Classification of Fuel Cells

9.4.1. Ambient Temperature Fuel Cells

9.4.2. Alkaline Fuel Cells

9. A3 Polymer Electrolyte Membrane Fuel Cells (PEMFCs)

9.4.4. Direct Alcohol Fuel Cells

9.4.5. Bioelectrochemical Fuel Cells

9.4.6. Intermediate Temperature Fuel Cells

9.4.7. Phosphoric Acid Fuel Cell (PAFC)

9.4.8. Molten Carbonate Fuel Cells (MCFC)

9.4.9. High Temperature Solid Oxide Fuel Cells (SOFC)

9.5. Applications of Fuel Cells

9.6. Fuel Cells in Energy Storage Systems

10. Flow Batteries

10.1. The Iron/Chromium System

10.2. The Iron/Vanadium System

10.3. The Iron/Cadmium System

10.4. The Bromine/Polysulfide System

10.5. The All-Vanadium System

10.6. The Vanadium/Bromine System

10.7. Actinide RFBs

10.8. All-Organic RFBs

10.9. Nonaqueous RFBs

10.10. Hybrid Systems

10.11. The Zinc/Cerium System

10.12. The Zinc/Bromine System

10.13. The Zinc/Organic System

10.14. The Cadmium/Organic System

10.15. The Lead/Lead Dioxide System

10.16. The Cadmium/Lead Dioxide System

10.17. The All-Copper System

10.18. The Zinc/Nickel System

10.19. The Lithium/LiFeP04 System

10.20. Vanadium Solid-Salt Battery

10.21. Vanadium-Dioxygen System

10.22. Electrochemical Flow Capacitor

10.23. Current State and Perspectives

11. Supercapacitors

11.1. Classification of Supercapacitors

11.2. Electrical Double-Layer Capacitors

11.2.1. Electrolytes for EDLCs

11.2.2. Electrode Materials for EDLCs

11.2.3. Electrochemical Performance of EDLCs

11.3. Pseudocapacitors

11.3.1. RuO2

11.3.2. MnO2

11.3.3. Intrinsically Conducting Polymers

11.3.4. Redox Couples

11.3.5. Electrochemical Performance of Pseudocapacitors

11.4. Hybrid Capacitors

11.4.1. Negative Electrode Materials

11.4.2. Positive Electrode Materials

11.4.3. Electrochemical Performance of Hybrid Capacitors

11.5. Testing of Supercapacitors

11.6. Commercially Available Supercapacitors

11.7. Application of Supercapacitors

11.7.1. Uninterruptible Power Sources

11.7.2. Transportation

11.7.3. Smart Grids

11.7.4. Military Equipment

11.7.5. Other Civilian Applications.

Notes:

Includes bibliographical references and index.

Local Notes:

Acquired for the Penn Libraries with assistance from the Alumni and Friends Memorial Book Fund.

ISBN:

9783527334315

3527334319

OCLC:

1259543986

Publisher Number:

99990840051