Energy Storage Materials
Innovations and Emerging Trends
- 1st Edition - November 1, 2026
- Latest edition
- Editors: Sunaja Devi K. R, Dephan Pinheiro, Habil. Martin Mkandawire
- Language: English
Energy Storage Materials: Innovations and Emerging Trends addresses the urgent global need for advanced, sustainable energy storage solutions. As the transition to renewable energy… Read more
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Description
Description
Energy Storage Materials: Innovations and Emerging Trends addresses the urgent global need for advanced, sustainable energy storage solutions. As the transition to renewable energy accelerates, the demand for high-performance, cost-effective, and environmentally friendly storage systems has never been greater. This scientific reference fills a critical gap by focusing on the latest developments in materials chemistry, nanotechnology, and device engineering, offering a consolidated resource for researchers and professionals navigating the rapidly evolving landscape of energy storage technologies. The contents are organized into three distinct parts: fundamentals of energy storage, advanced functional materials, and emerging technologies. Chapters provide in-depth coverage of core concepts, including design metrics, battery principles, and the optimization of electrolytes and separators. The book explores the synthesis, properties, and applications of cutting-edge materials such as carbon quantum dots, graphene derivatives, metal oxides and sulfides, conducting polymers, MXenes, MBenes, organometallic frameworks, MOFs, and their composites. It further examines sustainable and adaptive solutions including biomass-derived electrodes, hydrogel-based materials, self-healing systems, thin-film devices, and computational modeling, culminating in a forward-looking analysis of market trends and future directions. The book delivers essential benefits to its audience by providing a holistic, material-centric perspective, integrating comparative analyses, and highlighting practical applications for next-generation batteries and supercapacitors. Each chapter concludes with critical insights into research challenges and opportunities, guiding scientists, engineers, and educators toward innovative solutions for clean energy storage.
Key features
Key features
- Integrates advances from materials science, nanotechnology, and electrochemistry for a unified perspective
- Focuses on next-generation materials including 2D materials, MXenes, metal-organic frameworks, and hybrid nanocomposites
- Presents comparative analyses of material systems tailored for batteries and supercapacitors
- Guides future research through critical analysis of emerging trends and bottlenecks
- Addresses sustainability and scalable synthesis for real-world energy storage applications
Readership
Readership
Postgraduate students in materials science and energy engineering, early-career researchers, doctoral candidates, and faculty members actively engaged in the synthesis, characterization, and application of advanced materials for energy storage technologies; It can also act as a valuable reference for professionals and engineers working in industries related to energy storage devices such as batteries, supercapacitors, and fuel cells
Table of contents
Table of contents
Part I: Fundamentals of Energy Storage
1. Energy Storage Fundamentals: Design and Performance Metrics
2. Essentials of Battery Technology: Principles and Performance Indicators
3. Electrolytes and Separators in Energy Storage: Optimizing Ion Transport and Device Stability
Part II: Advanced Functional Materials for Energy Storage Systems
4. Carbon Quantum Dots and Composite Materials: Versatile Platforms for Energy Storage
5. Graphene-Based Materials: Engineering Advanced Energy Storage Solutions
6. Metal Oxides: High-Performance Electrode Materials for Batteries and Supercapacitors
7. Metal Sulfides: Promising Electrode Materials for Energy Storage Systems
8. Conducting Polymers in Energy Storage Systems
9. MXenes: Emerging 2D Carbides and Nitrides for Next-Generation Energy Storage
10. MBenes: Emerging 2D Boride Materials for Energy Storage Systems
11. Organometallic Frameworks: Tunable Architectures for Electrochemical Energy Storage
12. MOF-Derived Porous Materials: Bridging Structural Design and Energy Applications
13. MOF/MXene Composites: Synergistic Architectures for High-Performance Energy Devices
14. MXene-Polymer Composites: Engineering Conductive and Flexible Energy Storage Materials
Part III: Emerging Technologies and Future Directions
15. Biomass-Derived Materials: Green and Sustainable Electrodes for Energy Storage
16. Hydrogel-Based Electrodes: Soft and Flexible Materials for Energy Storage
17. Self-Healing Energy Storage Materials: Adaptive Solutions for Long-Term Stability
18. Thin-Film Energy Storage Devices: Nanoscale Engineering for Sustainable Energy Solutions
19. Computational Modeling in Energy Storage: Designing Materials and Predicting Performance
20. Energy Storage Revolution: Challenges, Breakthroughs, and Market Prospects
1. Energy Storage Fundamentals: Design and Performance Metrics
2. Essentials of Battery Technology: Principles and Performance Indicators
3. Electrolytes and Separators in Energy Storage: Optimizing Ion Transport and Device Stability
Part II: Advanced Functional Materials for Energy Storage Systems
4. Carbon Quantum Dots and Composite Materials: Versatile Platforms for Energy Storage
5. Graphene-Based Materials: Engineering Advanced Energy Storage Solutions
6. Metal Oxides: High-Performance Electrode Materials for Batteries and Supercapacitors
7. Metal Sulfides: Promising Electrode Materials for Energy Storage Systems
8. Conducting Polymers in Energy Storage Systems
9. MXenes: Emerging 2D Carbides and Nitrides for Next-Generation Energy Storage
10. MBenes: Emerging 2D Boride Materials for Energy Storage Systems
11. Organometallic Frameworks: Tunable Architectures for Electrochemical Energy Storage
12. MOF-Derived Porous Materials: Bridging Structural Design and Energy Applications
13. MOF/MXene Composites: Synergistic Architectures for High-Performance Energy Devices
14. MXene-Polymer Composites: Engineering Conductive and Flexible Energy Storage Materials
Part III: Emerging Technologies and Future Directions
15. Biomass-Derived Materials: Green and Sustainable Electrodes for Energy Storage
16. Hydrogel-Based Electrodes: Soft and Flexible Materials for Energy Storage
17. Self-Healing Energy Storage Materials: Adaptive Solutions for Long-Term Stability
18. Thin-Film Energy Storage Devices: Nanoscale Engineering for Sustainable Energy Solutions
19. Computational Modeling in Energy Storage: Designing Materials and Predicting Performance
20. Energy Storage Revolution: Challenges, Breakthroughs, and Market Prospects
Product details
Product details
- Edition: 1
- Latest edition
- Published: November 1, 2026
- Language: English
About the editors
About the editors
SR
Sunaja Devi K. R
Dr. Sunaja Devi K. R. completed her Master’s in Chemistry from Mahatma Gandhi University, Kerala, India, in 1999, and received her PhD in Chemistry from Cochin University of Science and Technology, Kochi, India. She is currently working as a professor at the Department of Chemistry, CHRIST (Deemed to be University), Bangalore. Her research interests include Nanochemistry, Organocatalysis, Material science, MXene, Photocatalysis, Energy storage and production. Throughout her career, she has published more than 100 peer-reviewed papers in journals and has 6 patents to her credit. According to Google Scholar, her h-index stands at 20 (Citations more than 1000). In addition, she also serves as a reviewer in several reputed peer-reviewed journals.
Affiliations and expertise
Professor, Department of Chemistry, CHRIST (Deemed to be University), Bangalore, IndiaDP
Dephan Pinheiro
Dr Dephan Pinheiro completed his Master’s in Chemistry from Bharathidasan University, Tiruchirappalli, in 1989, and completed his PhD from CHRIST (Deemed to be University), Bangalore, India. He is currently working as a professor at the Department of Chemistry, CHRIST (Deemed to be University), Bangalore, India. His research
interests include Nanochemistry, Catalysis, and Materials science.
Affiliations and expertise
Professor, Department of Chemistry, CHRIST (Deemed to be University), Bangalore, IndiaHM
Habil. Martin Mkandawire
Martin Mkandawire is a Professor of Solid-State Chemistry and the Chair of the Chemistry Department at Cape Breton University in Nova Scotia, Canada. He holds a Habilitation degree with a venia legendi and a Doctorate (Dr. rer. nat.). His research specializes in smart and advanced materials and technologies, aimed at providing cost-effective and energy-efficient solutions for medical and environmental applications. With over 200 publications to his name, including journal articles, book chapters, conference proceedings, and abstracts, he has also authored and edited three scientific books as well as two poetry anthologies. In addition, he serves as an adjunct professor at both Dalhousie University and Karunya University in India and has been appointed as an Extraordinary Professor at North-West University in South Africa.
Affiliations and expertise
Professor of Solid-State Chemistry and the Chair of the Chemistry Department at Cape Breton University in Nova Scotia, Canada