Nanostructured Materials for Supercapacitors

This book covers nanostructure materials for application as supercapacitors, highlighting their properties for energy storage applications. It reports approaches to increasing their specific surfaces for improved electrical storage capacities. It consolidates information on synthesis, characterization, and application, including experimental and theoretical studies on nanomaterials and their composites.

Format: Hardback
Length: 644 pages
Publication date: 20 May 2022
Publisher: Springer Nature Switzerland AG

This comprehensive book delves into the realm of nanostructure materials, focusing on their application as supercapacitors. It emphasizes the unique properties that make these materials highly suitable for energy storage purposes. The book provides detailed reports on various strategies employed to enhance their electronic, electrical, and thermal properties, thereby increasing their specific surface areas and improving their electrical storage capabilities. By consolidating information on synthesis, characterization, and application, this book offers a comprehensive understanding of supercapacitors. It includes detailed characterization, mechanistic approaches, and theoretical considerations, providing a deep insight into the progress made in experimental and theoretical studies on the properties of nanomaterials and their polymer and other composite counterparts.

This comprehensive book delves into the realm of nanostructure materials, focusing on their application as supercapacitors. It emphasizes the unique properties that make these materials highly suitable for energy storage purposes. The book provides detailed reports on various strategies employed to enhance their electronic, electrical, and thermal properties, thereby increasing their specific surface areas and improving their electrical storage capabilities. By consolidating information on synthesis, characterization, and application, this book offers a comprehensive understanding of supercapacitors. It includes detailed characterization, mechanistic approaches, and theoretical considerations, providing a deep insight into the progress made in experimental and theoretical studies on the properties of nanomaterials and their polymer and other composite counterparts.

The book begins by introducing the fundamental principles and characteristics of nanostructure materials, including their size, shape, and composition. It then explores the various methods used to synthesize these materials, such as chemical vapor deposition, sol-gel synthesis, and template-based synthesis. The authors discuss the importance of controlling the nanostructure of the materials to achieve optimal performance for supercapacitors.

Next, the book focuses on the characterization of nanostructure materials. It discusses the techniques used to examine their structure, morphology, and chemical composition, such as X-ray diffraction, scanning electron microscopy, and energy-dispersive X-ray spectroscopy. The authors also discuss the use of advanced characterization methods, such as Raman spectroscopy, Fourier transform infrared spectroscopy, and electrochemical impedance spectroscopy, to gain deeper insights into the electronic and chemical properties of these materials.

The third section of the book explores the electrical and thermal properties of nanostructure materials. It discusses the mechanisms behind their electrical behavior, including charge storage, capacitance, and resistance. The authors also discuss the factors that influence their thermal properties, such as thermal conductivity, specific heat, and thermal expansion. The book provides detailed reports on the strategies employed to enhance the electrical and thermal properties of these materials, such as doping, surface modification, and composite formation.

The fourth section of the book focuses on the application of nanostructure materials as supercapacitors. It discusses the different types of supercapacitors, including carbon-based supercapacitors, metal-oxide-based supercapacitors, and polymer-based supercapacitors. The authors provide detailed reports on the synthesis, characterization, and performance of these supercapacitors, including their energy density, power density, and cycling stability. The book also discusses the challenges and opportunities associated with the development of supercapacitors, such as their scalability, cost-effectiveness, and environmental impact.

In conclusion, this book is a valuable resource for researchers, engineers, and students interested in the field of nanostructure materials and their application as supercapacitors. It provides a comprehensive overview of the synthesis, characterization, and application of these materials, including detailed characterization, mechanistic approaches, and theoretical considerations. The book also highlights the progress made in experimental and theoretical studies on the properties of nanomaterials and their polymer and other composite counterparts. By consolidating information on synthesis, characterization, and application, this book offers a comprehensive understanding of supercapacitors and their potential for future energy storage applications.

Weight: 1142g
Dimension: 235 x 155 (mm)
ISBN-13: 9783030993016
Edition number: 1st ed. 2022