Polymer Electrolyte-Based Electrochemical Devices

Polymer Electrolyte–Based Electrochemical Devices: Advances, provides a comprehensive overview of energy-related polymer electrolyte-based technologies, covering their theoretical and applied aspects. It discusses the physical-chemical, electrochemical, and mechanical properties of smart materials and offers protocols for their optimization. Examples of actual prototypes are provided, along with an examination of their environmental impact.

Format: Paperback / softback
Length: 470 pages
Publication date: 01 August 2023
Publisher: Elsevier - Health Sciences Division

Polymer Electrolyte-Based Electrochemical Devices: Advances, presents a comprehensive exploration of the theoretical and practical aspects of energy-related polymer electrolyte-based technologies. The book offers in-depth insights into the thermodynamic and fundamental requirements for innovative smart materials, encompassing fuel cells, electrolyzers, batteries, sensors, and devices for pollution abatement. It delves into the physical-chemical, electrochemical, and mechanical properties of these smart materials, covering fundamental analysis and modeling to optimize their application in terms of conductivity, chemical stability, and kinetic properties. Detailed protocols for operation are proposed, encompassing component development for enhanced functionality, cost-effectiveness, and scalability. By examining examples of actual prototypes derived from recent research findings, analyzing the requirements and cost estimates for large-scale production and implementation, as well as their integration into existing systems, the environmental impact of various electrochemical applications is also assessed.

Introduction:
Polymer electrolyte-based electrochemical devices have gained significant attention in recent years due to their potential for energy storage, conversion, and pollution control. These devices, which utilize polymer membranes as electrolytes, offer several advantages over traditional electrochemical systems, including high energy density, flexibility, and cost-effectiveness. In this book, we will provide a comprehensive overview of the theoretical and applied aspects of energy-related polymer electrolyte-based technologies.

Thermodynamic Requirements:
One of the key challenges in developing polymer electrolyte-based devices is meeting the thermodynamic requirements for efficient energy conversion and storage. The book discusses the thermodynamic principles governing the operation of polymer electrolyte-based devices, including fuel cells, electrolyzers, batteries, and sensors. It covers the basic principles of electrochemistry, including the redox reactions, ion transport, and electrochemical kinetics. By understanding these principles, researchers can optimize the design and performance of polymer electrolyte-based devices.

Basic Properties of Smart Materials:
Smart materials, such as fuel cells, electrolyzers, batteries, and sensors, have unique physical-chemical, electrochemical, and mechanical properties that determine their performance and functionality. The book explores these properties in detail, covering topics such as material selection, synthesis, and characterization. It also discusses the fundamental analysis and modeling techniques used to optimize the application of smart materials in terms of conductivity, chemical stability, and kinetic properties.

Component Development:
Component development is a critical aspect of optimizing the performance and cost-effectiveness of polymer electrolyte-based devices. The book discusses the development of key components, such as polymer membranes, electrodes, and catalysts, for polymer electrolyte-based devices. It covers topics such as material selection, synthesis, and characterization, as well as the design and optimization of these components. By developing efficient and cost-effective components, researchers can enhance the performance and scalability of polymer electrolyte-based devices.

Operation Protocols:
Detailed protocols for operation are essential for the successful implementation of polymer electrolyte-based devices. The book provides comprehensive protocols for the operation of fuel cells, electrolyzers, batteries, and sensors. It covers topics such as cell assembly, electrolyte preparation, and cell testing. By following these protocols, researchers can ensure the reproducibility and reliability of their results.

Examples of Actual Prototype:
To illustrate the practical applications of polymer electrolyte-based technologies, the book includes examples of actual prototypes based on recent research findings. These prototypes demonstrate the potential of polymer electrolyte-based devices for various energy storage and conversion applications, such as electric vehicles, renewable energy systems, and water treatment. By analyzing the requirements and cost estimates for large-scale production and implementation, as well as their integration into existing systems, the environmental impact of these prototypes is also examined.

Conclusion:
Polymer Electrolyte-Based Electrochemical Devices: Advances provides a comprehensive overview of the theoretical and applied aspects of energy-related polymer electrolyte-based technologies. By exploring the thermodynamic requirements, basic properties of smart materials, component development, operation protocols, and examples of actual prototypes, the book offers valuable insights into the potential of these devices for sustainable energy and environmental applications. As the field of polymer electrolyte-based technologies continues to evolve, this book will serve as a valuable resource for researchers, engineers, and policymakers interested in advancing these innovative technologies.

Dimension: 229 x 152 (mm)
ISBN-13: 9780323897846