Sustainable Waste-derived Electrochemical Energy Device Materials
A Circular Economy Approach
- 1st Edition - January 1, 2027
- Latest edition
- Editors: Bhoomika Yadav, Suresh Sundaramurthy, Kamal Krishna Kar
- Language: English
Sustainable Waste-derived Electrochemical Energy Device Materials: A Circular Economy Approach aims to address the growing need for sustainable materials in the energy and semico… Read more
Description
Description
Sustainable Waste-derived Electrochemical Energy Device Materials: A Circular Economy Approach aims to address the growing need for sustainable materials in the energy and semiconductor industries. With the global shift towards renewable energy sources, there's a significant demand for supercapacitors and battery electrode materials that are not only efficient but also environmentally friendly. This book intends to bridge that gap by exploring the use of waste-derived materials to produce sustainable supercapacitors and battery electrodes. The book covers the chemical and physical properties of these sustainable materials, their environmental impact, and the economic networks associated with their use. By emphasizing the circular economy, the book aims to promote resource efficiency and waste reduction, aligning with global UN sustainability goals and carbon neutrality targets. The book will serve as a valuable reference resource for academics, industry professionals, and policymakers working towards sustainable energy solutions. It promotes innovative solutions to environmental challenges and offers economic and technical insights into the use of waste-derived materials.
Key features
Key features
- Focus on the circular economy and waste-derived materials for application in sustainable energy devices
- Comprehensive coverage of sustainable materials and advanced recycling techniques
- Inclusion of techno-economic analysis, market impacts, and global regulations for global economy implementation
- Case studies of successful circular economy implementations via practical applications
- Insights into biocompatible electrolyte and packaging materials
- Emphasis on the carbon circular economy, the role of AI/ML in process optimization, and future opportunities for sustainable energy storage
Readership
Readership
Academic researchers in materials science, chemical engineering, energy storage, and environmental science - Industry professionals in energy storage, materials science, and nanotechnology - Small scale industries focusing on sustainable electronics
Table of contents
Table of contents
I. Introduction
1. Introduction to waste-derived materials for the Energy and Semiconductor sectors
2. Circular Economy approach: Recycling and Reuse of waste-derived materials
II. Sustainable materials preparation from biomass
3. Sustainable electrode materials from Agricultural residues
4. Carbon nanomaterial types from waste-derived materials
5. Green synthesis of metal and metal oxide nanoparticles for electrode materials from plant extracts
6. Development of biocompatible and biodegradable electrodes for supercapacitors
7. Understanding the structure and properties of waste-derived materials for energy storage
8. Biocompatible electrolyte and packaging materials for sustainable energy storage devices
9. Organic electrode materials for supercapacitor and Battery applications
10. Electrochemical characteristics and sustainability factors for Energy and Semiconductor applications
11. Use of sustainable electrodes in electrochemical synthesis processes to reduce environmental impact
12. Natural materials for energy storage
13. Development of Sustainable manufacturing processes from waste-derived materials for reducing the carbon footprint
III. Recycling methods for materials from biomass and other sources
14. Waste-derived conversion processes and their characteristics, and suitability for Sustainable electrode materials
15. Utilization of industrial slag and fly ash into electrode materials for supercapacitor and Battery applications
16. Conversion of solar panel wastes, battery wastes and E-wastes into electrode materials
IV. Computation/AI assisted solutions in sustainable energy storage
17. AI/ML algorithms to predict battery life, optimize charging cycles, and enhance safety
18. Using AI to design and optimize biodegradable electrode materials for supercapacitors
19. Machine learning algorithms for real-time detection and quality control in semiconductor and battery applications
20. AI/ML to develop efficient recycling processes for semiconductor materials
21. AI-driven simulations to discover new sustainable electrodes from waste-derived materials
V. Circular economy/Integrated solution/application in sustainable energy storage
22. Circular Economy approach in Energy and Semiconductor Sectors
23. Circular Economy practices, post-mortem analysis of batteries
24. Global regulations for successful circular economy implementation in sustainable energy storage
25. Developing infrastructure for waste-derived materials reuse and recycling
26. Application of sustainable electrode materials in electrocatalysis for energy production
27. Integrated solution and techno-economic analysis of Energy and Semiconductor sectors Applications of Sustainable electrode materials
VI. Policy, regulations, and impacts
28. Policy and Implementing market-based incentives to promote successful circular economy practices in waste-derived materials for energy and semiconductor sectors
29. Government regulations and policies to support successful circular economy initiatives from waste-derived materials
1. Introduction to waste-derived materials for the Energy and Semiconductor sectors
2. Circular Economy approach: Recycling and Reuse of waste-derived materials
II. Sustainable materials preparation from biomass
3. Sustainable electrode materials from Agricultural residues
4. Carbon nanomaterial types from waste-derived materials
5. Green synthesis of metal and metal oxide nanoparticles for electrode materials from plant extracts
6. Development of biocompatible and biodegradable electrodes for supercapacitors
7. Understanding the structure and properties of waste-derived materials for energy storage
8. Biocompatible electrolyte and packaging materials for sustainable energy storage devices
9. Organic electrode materials for supercapacitor and Battery applications
10. Electrochemical characteristics and sustainability factors for Energy and Semiconductor applications
11. Use of sustainable electrodes in electrochemical synthesis processes to reduce environmental impact
12. Natural materials for energy storage
13. Development of Sustainable manufacturing processes from waste-derived materials for reducing the carbon footprint
III. Recycling methods for materials from biomass and other sources
14. Waste-derived conversion processes and their characteristics, and suitability for Sustainable electrode materials
15. Utilization of industrial slag and fly ash into electrode materials for supercapacitor and Battery applications
16. Conversion of solar panel wastes, battery wastes and E-wastes into electrode materials
IV. Computation/AI assisted solutions in sustainable energy storage
17. AI/ML algorithms to predict battery life, optimize charging cycles, and enhance safety
18. Using AI to design and optimize biodegradable electrode materials for supercapacitors
19. Machine learning algorithms for real-time detection and quality control in semiconductor and battery applications
20. AI/ML to develop efficient recycling processes for semiconductor materials
21. AI-driven simulations to discover new sustainable electrodes from waste-derived materials
V. Circular economy/Integrated solution/application in sustainable energy storage
22. Circular Economy approach in Energy and Semiconductor Sectors
23. Circular Economy practices, post-mortem analysis of batteries
24. Global regulations for successful circular economy implementation in sustainable energy storage
25. Developing infrastructure for waste-derived materials reuse and recycling
26. Application of sustainable electrode materials in electrocatalysis for energy production
27. Integrated solution and techno-economic analysis of Energy and Semiconductor sectors Applications of Sustainable electrode materials
VI. Policy, regulations, and impacts
28. Policy and Implementing market-based incentives to promote successful circular economy practices in waste-derived materials for energy and semiconductor sectors
29. Government regulations and policies to support successful circular economy initiatives from waste-derived materials
Product details
Product details
- Edition: 1
- Latest edition
- Published: January 1, 2027
- Language: English
About the editors
About the editors
BY
Bhoomika Yadav
Dr. Bhoomika Yadav is an Assistant Professor in the Department of Materials Science and Metallurgical Engineering at Chhatrapati Shahu Jee Maharaj University, Kanpur, India. She earned her M.Sc. from DDU Gorakhpur University, M.Tech from IIT BHU, and Ph.D. from IIT Kanpur. Her research focuses on electroceramics, specifically the utilization of high dielectric constant materials for miniaturized capacitors and supercapacitors, solid-state batteries, and the extraction of valuable metals by recycling waste Li-Ion batteries and PCB boards. Dr. Yadav has extensive teaching experience and has guided numerous students in their academic research.
Affiliations and expertise
Researcher, Institut national de la recherche scientifique’s Centre Eau Terre Environnement, CanadaSS
Suresh Sundaramurthy
Suresh Sundaramurthy is the Head of the Department of Chemical Engineering at Maulana Azad National Institute of Technology, Bhopal, India. He earned his Ph.D. in Chemical Engineering from the Indian Institute of Technology Roorkee and has held postdoctoral, visiting faculty, and research positions at institutions including CUNY (USA), AIT Thailand, JNCASR Bengaluru, IIT Kanpur, and Pondicherry University. His research interests span catalysts, reactor design, environmental biotechnology, waste‑to‑energy, nanoengineered materials, critical minerals, decarbonation, and biofuels, green hydrogen.
Affiliations and expertise
Head of Department, Chemical Engineering, Maulana Azad National Institute of Technology, Bhopal, IndiaKK
Kamal Krishna Kar
Prof. Kamal Krishna Kar is a Champa Devi Gangwal Chair Professor at the Indian Institute of Technology Kanpur. He has pursued higher studies at IIT Kharagpur and Iowa State University, USA. His research encompasses nanostructured carbon materials, nanocomposites, functionally graded materials, and smart materials for various applications. He has held esteemed positions, including Umang Gupta Institute Chair Professor and Editor-in-Chief roles in prominent scientific journals. Prof. Kar has guided numerous doctoral and master’s students and contributed to the advanced nanoengineering materials laboratory at IIT Kanpur.
Affiliations and expertise
Chair Professor, Indian Institute of Technology Kanpur, India