Green Sustainable Process for Chemical and Environmental Engineering and Science
Solid-State Energy Storage - A Path to Environmental Sustainability
- 1st Edition - September 21, 2022
- Imprint: Elsevier
- Editors: Alevtina Smirnova, Abu Numan-Al-Mobin, Inamuddin
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 0 6 3 5 - 7
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 9 8 1 7 - 8
Green Sustainable Process for Chemical and Environmental Engineering and Science: Solid-State Energy Storage - A Path to Environmental Sustainability offers an in-depth analys… Read more
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Request a sales quoteGreen Sustainable Process for Chemical and Environmental Engineering and Science: Solid-State Energy Storage - A Path to Environmental Sustainability offers an in-depth analysis of the synthesis methods, manufacturing techniques and underlying mechanisms of ionic and electronic-ion transport in various single phase and multi-phase components for electric power storage, such as lithium and sodium ion batteries, sulfur batteries, and lithium-metal electrochemical systems. Though solid-state batteries are not yet available on the market, many large corporations and small companies pursue the goal of implementing this technology for numerous applications and its transfer to other markets.
- Includes information regarding solid-state energy storage technology as key to a green and sustainable environment
- Describes recent advances in the areas of solid-state ionics, electrochemistry, materials science and engineering, and sustainable energy
- Introduces materials synthesis approaches, including chemicals in aqueous and organic solutions, mechanical ball-milling, and physical approaches, including ink-jet and physical vapor deposition
- Provides electrochemical data and in-situ-operando approaches for the evaluation of solid-state battery performance
Academics, students interested in next-generation battery technologies pertinent to electric vehicles (EVs), Internet of Things (IoT), electric power grids, and medical applications
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- 1: Next-generation battery technology based on solid-state electrolytes
- Abstract
- Acknowledgments
- Conflict of interest
- 1.1: Introduction
- 1.2: History of ion conduction in solids and solid-state batteries
- 1.3: Summary and outlook
- References
- 2: Solid-state batteries based on composite polymer electrolytes
- Abstract
- 2.1: Introduction
- 2.2: Fundamentals of composite polymer electrolytes
- 2.3: Compatibility between composite polymer electrolytes and electrodes
- 2.4: Fabrication methods of composite polymer electrolytes membranes
- 2.5: Assembly of solid-state batteries with composite polymer electrolytes
- 2.6: Summary
- References
- 3: Composite lithium metal anodes for solid-state battery applications
- Abstract
- Acknowledgments
- 3.1: Introduction
- 3.2: Methods to fabricate composite lithium metal anode
- 3.3: Solid-state battery with composite lithium metal anode
- 3.4: Conclusions and outlook
- References
- 4: Challenges of lithium dendrite formation in solid-state batteries
- Abstract
- 4.1: Introduction
- 4.2: Lithium dendrite formation and growth
- 4.3: Characterization of lithium dendrite formation and growth
- 4.4: Lithium dendrite prevention
- 4.5: Functionalization of lithium metal-based anodes
- 4.6: Architectures of lithium powder based anodes
- 4.7: Conclusions
- References
- 5: Silicon-based lithium-ion battery anodes and their application in solid-state batteries
- Abstract
- Acknowledgments
- 5.1: Introduction
- 5.2: Synthesis approaches toward silicon-based nanostructures
- 5.3: Silicon-based nanocomposites
- 5.4: Binders for silicon-based lithium-ion battery anodes
- 5.5: Low-dimensional silicene as a potential material for lithium-ion battery anodes
- 5.6: Lithium-ion solid-state battery with silicon-based anode: Design and performance
- 5.7: Conclusions
- References
- 6: Battery cathodes for lithium-ion batteries with liquid and solid-state electrolytes
- Abstract
- 6.1: Introduction
- 6.2: Crystal structure and doping in lithium-ion battery intercalation cathodes
- 6.3: Cathode materials synthesis, morphology, and properties evaluation
- 6.4: Cathodes in batteries with solid-state electrolytes
- 6.5: Cathode materials with polymer electrolytes
- 6.6: Conclusions
- References
- 7: In situ/operando methods for investigation of ionic transport mechanisms in solid-state architectures
- Abstract
- 7.1: Development of solid-state electrolyte batteries
- 7.2: Current limits and challenges of SSEs in solid-state batteries
- 7.3: In situ/operando characterization on solid-state architectures
- 7.4: Conclusions
- References
- 8: Beyond lithium: Solid-state sodium-ion batteries and their potential applications
- Abstract
- 8.1: Introduction
- 8.2: Solid-state sodium-ion batteries: Market analysis and potential applications
- 8.3: Materials for solid-state sodium-ion batteries
- 8.4: Conclusions
- References
- 9: Decision making in solid-state battery manufacturing
- Abstract
- 9.1: Introduction
- 9.2: Manufacturing of lithium-ion batteries with liquid and solid-state electrolyte
- 9.3: Prognostics of the next generation of solid-state battery health
- 9.4: Understanding the decision-making mechanism toward sustainable solid-state battery cell manufacturing
- 9.5: Analytical models to address the battery manufacturing process
- 9.6: Conclusion
- References
- 10: Application of supersonic cold spray for solid-state battery manufacturing
- Abstract
- 10.1: Introduction
- 10.2: Supersonic acceleration parameters and substrate requirement
- 10.3: Materials for high-pressure supersonic cold spray deposition
- 10.4: Applications of supersonic cold spray
- 10.5: Conclusions
- References
- 11: Potential applications and impacts of solid-state energy storage in power grids
- Abstract
- 11.1: Introduction
- 11.2: Potential applications of solid-state energy storage in power systems
- 11.3: Potential impacts of solid-state energy storage in power systems
- 11.4: Summary
- References
- 12: Machine learning approaches to estimate the health state of next-generation energy storage
- Abstract
- 12.1: Introduction
- 12.2: State of health (SOH) estimation methods
- 12.3: Machine learning methods for state-of-health assessment
- 12.4: Challenges and opportunities for machine learning (ML)-based models for SOH evaluation
- 12.5: Conclusions
- References
- 13: Principles of the life cycle assessment for emerging energy storage technologies
- Abstract
- 13.1: Products end-life, recycling, and LCA
- 13.2: LCA mathematical model and its application in energy storage
- 13.3: Application of the LCA models for lithium-ion and lithium metal batteries
- 13.4: Solid-state battery technology
- 13.5: Conclusions
- References
- Index
- Edition: 1
- Published: September 21, 2022
- No. of pages (Paperback): 422
- No. of pages (eBook): 422
- Imprint: Elsevier
- Language: English
- Paperback ISBN: 9780323906357
- eBook ISBN: 9780323998178
AS
Alevtina Smirnova
Dr. Smirnova’s research interests are focused on developing efficient and eco-friendly electric power generation and storage devices, such as supercapacitors, fuel cells, and batteries. She authored and co-authored over 200 publications, such as a o book, 13 book chapters, 5 patents, 6 patent applications, and over 180 manuscripts in peer reviewed journals and proceedings. Her research incorporate multi-disciplinary efforts regarding ionic and electronic transport mechanisms in solid and polymer materials, heterogeneous low and high temperature electro-catalysis, and new architectural designs of ionic/electronic conductors and nanocomposites produced by various materials deposition approaches, such supercritical fluids, physical vapor deposition, screen-printing, electron beam, and aerosol ink-jet printing.
Affiliations and expertise
Chemistry, Biology, and Health Sciences Department, South Dakota School of Mines and Technology (SDSMT), USAAN
Abu Numan-Al-Mobin
Research Scientist in the Chemistry, Biology, and Health Sciences Department, South Dakota School of Mines and Technology (SDSMT), USA
Affiliations and expertise
Chemistry, Biology, and Health Sciences Department, South Dakota School of Mines and Technology (SDSMT), USAI
Inamuddin
Dr. Inamuddin is an Assistant Professor at the Department of Applied Chemistry at the Zakir Husain College of Engineering and Technology, Aligarh Muslim University, Aligarh, India. He has extensive research experience in multidisciplinary fields of analytical chemistry, materials chemistry, electrochemistry, renewable energy, and environmental science. He has worked on different research projects funded by various government agencies and universities and is the recipient of several awards, including the Fast Track Young Scientist Award and the Young Researcher of the Year Award 2020, Aligarh Muslim University, India. He has published nearly 200 research articles in various international scientific journals, 18 book chapters, and numerous edited books with well-known publishers.
Affiliations and expertise
Assistant Professor, Department of Applied Chemistry, Zakir Husain College of Engineering and Technology, Faculty of Engineering and Technology, Aligarh Muslim University, Aligarh, IndiaRead Green Sustainable Process for Chemical and Environmental Engineering and Science on ScienceDirect