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This book focusses on the current research on materials for advanced battery technologies and proposes future directions for different types of batteries to meet the current challenges associated with the fuel cell. Furthermore, it provides insights into scientific and practical issues in the development of various batteries like sodium, potassium, zinc, magnesium, aluminum, calcium, and dual metal ion, to bring a new perspective to storage technologies beyond lithium-ion batteries. It introduces different themes of batteries to evaluate the opportunities and challenges of these battery systems from a commercial aspect. Key features: Deals with different potential rechargeable battery systems as suitable substitutes for LIBs Discusses different investigated materials as anode, cathode, and electrolytes for different energy storage systems Provides a complete and comprehensive review of all the existing metal-ion batteries Includes practical challenges and future opportunities of each battery category Reviews commercial aspects of different battery systems This book is aimed at researchers, graduate students, and professionals in industrial and applied chemistry, renewable energy, clean and sustainable processes, chemical engineering, materials science, nanotechnology, and battery chemistry.
This book focusses on the current research on materials for advanced battery technologies and proposes future directions for different types of batteries to meet the current challenges associated with the fuel cell. Furthermore, it provides insights into scientific and practical issues in the development of various batteries like sodium, potassium, zinc, magnesium, aluminum, calcium, and dual metal ion, to bring a new perspective to storage technologies beyond lithium-ion batteries. It introduces different themes of batteries to evaluate the opportunities and challenges of these battery systems from a commercial aspect. Key features: Deals with different potential rechargeable battery systems as suitable substitutes for LIBs Discusses different investigated materials as anode, cathode, and electrolytes for different energy storage systems Provides a complete and comprehensive review of all the existing metal-ion batteries Includes practical challenges and future opportunities of each battery category Reviews commercial aspects of different battery systems This book is aimed at researchers, graduate students, and professionals in industrial and applied chemistry, renewable energy, clean and sustainable processes, chemical engineering, materials science, nanotechnology, and battery chemistry.
Electrochemical energy storage has played important roles in energy storage technologies for portable electronics and electric vehicle applications. During the past thirty years, great progress has been made in research and development of various batteries, in term of energy density increase and cost reduction. However, the energy density has to be further increased to achieve long endurance time. In this book, recent research and development in advanced electrode materials for electrochemical energy storage devices are presented, including lithium ion batteries, lithium-sulfur batteries and metal-air batteries, sodium ion batteries and supercapacitors. The materials involve transition metal oxides, sulfides, Si-based material as well as graphene and graphene composites.
This book details the latest R&D in electrochemical energy storage technologies for portable electronics and electric vehicle applications. During the past three decades, great progress has been made in R & D of various batteries in terms of energy density increase and cost reduction. One of the biggest challenges is increasing the energy density to achieve longer endurance time. In this book, recent research and development in advanced electrode materials for electrochemical energy storage devices is covered. Topics covered in this important book include: Carbon anode materials for sodium-ion batteries Lithium titanate-based lithium-ion batteries Rational material design and performance optimization of transition metal oxide-based lithium ion battery anodes Effects of graphene on the electrochemical properties of the electrode of lithium ion batteries Silicon-based lithium-ion battery anodes Mo-based anode materials for alkali metal ion batteries Lithium-sulfur batteries Graphene in Lithium-Ion/Lithium-Sulfur Batteries Graphene-ionic liquid supercapacitors Battery electrodes based on carbon species and conducting polymers Doped graphene for electrochemical energy storage systems Processing of graphene oxide for enhanced electrical properties
This volume covers recent advanced battery systems such as metal-ion, hybrid, and metal-air batteries. It includes an introduction to fluoride, potassium, zinc, chloride, aluminium, and iron-ion batteries; special or hybrid batteries are included, with calcium, nuclear, thermal, and lithium-magnesium hybrid batteries also explained. It summarizes the recent progress and chemistry behind the popular metal-air batteries, including a systematic overview of the components, design, and integration of these new battery technologies. Features: Covers recent battery technologies in detail, from the chemistry to advances in post-lithium-ion batteries. Various post-lithium-ion batteries are discussed in detail. Includes a section on ion batteries, exploring new types of metal-ion batteries. Focuses in each chapter on a particular battery type, including different metal-ion batteries such as zinc, potassium, aluminium, and their air version batteries. Provides authoritative coverage of scientific content via global contributing experts. This book is aimed at graduate students, researchers, and professionals in materials science, chemical and electrical engineering, and electrochemistry.
This volume focuses on alkaline metal-ion, redox flow, and metal sulfur batteries and provides details about the various kinds of advanced rechargeable batteries. It explains magnesium-ion batteries, sodium-ion batteries, metal sulfur batteries, and redox flow batteries with an introduction to rechargeable batteries and major upcoming batteries (magnesium-/sodium-ion batteries). Various kinds of redox flow batteries from introduction extending to the recent progress in redox flow batteries have been extensively discussed. Features: Covers recent battery technologies in detail, from chemistry to advances in post-lithium-ion batteries. Reviews magnesium-ion batteries, sodium-ion batteries, metal sulfur batteries, and redox flow batteries. Explains various metal sulfur batteries. Explores different types of redox flow batteries for large-scale energy storage application. Provides authoritative coverage of scientific contents via global contributing experts. This book is aimed at graduate students, researchers, and professionals in materials science, chemical and electrical engineering, and electrochemistry.
Develop the clean technologies of the future with these novel energy storage technologies Energy storage is a crucial component of the broader battle to develop clean energy sources and transform the power grid in light of advancing climate change. Numerous new energy storage technologies based on electrochemical redox reactions have recently been developed or proposed, promising to reduce costs and enable energy-dense devices and applications of many kinds. This urgent work demands to be incorporated into chemistry, materials science, and industry at every level. Towards Next Generation Energy Storage Technologies offers a comprehensive overview of these novel technologies and their applications. Beginning with an introduction to the fundamentals of electrochemistry and energy storage, it offers current and future research questions, design strategies, and much more. It is a must-own for scientists and engineers looking to develop the energy grid of the future. Towards Next Generation Energy Storage Technologies readers will also find: Summaries of state-of-the-art research and open challenges Detailed discussion of technologies including lithium-ion batteries, all-solid-state batteries, aqueous multi-valence energy storage systems, and more Discussion of applications including electric vehicles, aerospace devices, and many others Towards Next Generation Energy Storage Technologies is ideal for materials scientists, inorganic chemists, electrochemists, electronics engineers, and anyone working on the clean energy grid or electrical devices.
Multivalent-ion batteries, as promising alternative or supplementary technologies to lithium-ion batteries, have increasingly attracted attention recently. Various advanced materials have been presented to pursue potential breakthroughs in energy and power. Among them, vanadium (V)-based materials benefiting from abundant resources, various polymorphs and valences, especially most with large interlayer spacings, are good candidates for multivalent-ion storage. However, limited by multiple inherent issues, e.g., strong electrostatic interactions, poor electronic conductivity, structure collapse or materials dissolution under battery operation, etc., various strategies have sprung many advanced materials and applications and also brought about new challenges that are in urgent need to clarify and summarize. Hence, advanced V-based compounds developed for multivalent-ion storage in the past few years are selectively summarized and systematically analyzed, including vanadium oxides and sulfides, vanadates, and V-based MXenes and phosphates. Not only crystal structures and electrochemical properties but also mainstream ion storage mechanisms are critically reviewed. Through analyzing the challenges accompanying multivalent-ion storage, potential opportunities are anticipated.
Written by a group of top scientists and engineers in academic and industrial R&D, Lithium-Ion Batteries: Advanced Materials and Technologies gives a clear picture of the current status of these highly efficient batteries. Leading international specialists from universities, government laboratories, and the lithium-ion battery industry share th
Electrochemical Energy Storage Technologies Beyond Li-ion Batteries focuses on an overview of the current research directions to enable the commercial translation of electrochemical energy storage technologies. First, the principles of energy storage mechanisms and device design considerations are introduced. Then, organized by electrochemical energy storage technology, the advances in candidate materials and their path to commercialization and industrialization are discussed. Electrochemical energy storage technologies reviewed include rocking chair batteries, metal-air batteries, redox flow batteries, fuel cells, and supercapacitors. Electrochemical Energy Storage Technologies Beyond Li-ion Batteries is suitable for materials scientists and chemists in academia and industry. It may also be of interest to physicists and energy scientists and practitioners. Provides a thorough overview of candidate materials for electrochemical energy storage technologies, including batteries, fuel cells, and supercapacitors Summarizes fundamental principles of electrochemical energy storage such as energy storage mechanisms, device design considerations, and computational and characterization methods Discusses future opportunities and challenges of recycling of electrochemical energy storage technologies and non-lithium energy storage