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This book combines two areas of intense interest: nanotechnology, and energy conversion and storage devices. In particular, Li-ion batteries have enjoyed conspicuous success in many consumer electronic devices and their projected use in vehicles that will revolutionize the way we travel in the near future. For many applications, Li-ion batteries are the battery of choice. This book consolidates the scattered developments in all areas of research related to nanotechnology and lithium ion batteries.
A lithium-ion battery comprises essentially three components: two intercalation compounds as positive and negative electrodes, separated by an ionic-electronic electrolyte. Each component is discussed in sufficient detail to give the practising engineer an understanding of the subject, providing guidance on the selection of suitable materials in actual applications. Each topic covered is written by an expert, reflecting many years of experience in research and applications. Each topic is provided with an extensive list of references, allowing easy access to further information. Readership: Research students and engineers seeking an expert review. Graduate courses in electrical drives can also be designed around the book by selecting sections for discussion. The coverage and treatment make the book indispensable for the lithium battery community.
This book covers both the fundamental and applied aspects of advanced Na-ion batteries (NIB) which have proven to be a potential challenger to Li-ion batteries. Both the chemistry and design of positive and negative electrode materials are examined. In NIB, the electrolyte is also a crucial part of the batteries and the recent research, showing a possible alternative to classical electrolytes – with the development of ionic liquid-based electrolytes – is also explored. Cycling performance in NIB is also strongly associated with the quality of the electrode-electrolyte interface, where electrolyte degradation takes place; thus, Na-ion Batteries details the recent achievements in furthering knowledge of this interface. Finally, as the ultimate goal is commercialization of this new electrical storage technology, the last chapters are dedicated to the industrial point of view, given by two startup companies, who developed two different NIB chemistries for complementary applications and markets.
Electrochemical Energy: Advanced Materials and Technologies covers the development of advanced materials and technologies for electrochemical energy conversion and storage. The book was created by participants of the International Conference on Electrochemical Materials and Technologies for Clean Sustainable Energy (ICES-2013) held in Guangzhou, China, and incorporates select papers presented at the conference. More than 300 attendees from across the globe participated in ICES-2013 and gave presentations in six major themes: Fuel cells and hydrogen energy Lithium batteries and advanced secondary batteries Green energy for a clean environment Photo-Electrocatalysis Supercapacitors Electrochemical clean energy applications and markets Comprised of eight sections, this book includes 25 chapters featuring highlights from the conference and covering every facet of synthesis, characterization, and performance evaluation of the advanced materials for electrochemical energy. It thoroughly describes electrochemical energy conversion and storage technologies such as batteries, fuel cells, supercapacitors, hydrogen generation, and their associated materials. The book contains a number of topics that include electrochemical processes, materials, components, assembly and manufacturing, and degradation mechanisms. It also addresses challenges related to cost and performance, provides varying perspectives, and emphasizes existing and emerging solutions. The result of a conference encouraging enhanced research collaboration among members of the electrochemical energy community, Electrochemical Energy: Advanced Materials and Technologies is dedicated to the development of advanced materials and technologies for electrochemical energy conversion and storage and details the technologies, current achievements, and future directions in the field.
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
The rise of renewable energy responds to global warming, necessitating reliable storage like batteries. Though frequent use can affect their lifespan, these have become smaller, simpler, and more adaptable. Recent technological progress has improved batteries' longevity and efficiency, with costs dropping due to mass production. This book examines different battery types, their evolution, and the cutting-edge materials enhancing their performance, particularly focusing on metal oxides in various battery technologies. Exploring advanced materials for batteries is not just a theoretical exercise but a practical journey into the future of energy. This book is an essential guide, tracing the evolution from early battery technology to the latest innovations and equipping researchers, engineers, and students with the practical knowledge to drive the next wave of sustainable energy solutions. Key Features: · Provides a comprehensive resource for academics, researchers, and engineers in energy storage, with detailed insights into various battery types. · Discusses advanced materials for smart and small batteries. · Delves into cutting-edge materials designed for compact and efficient batteries. · Offers a visionary outlook on the evolution of battery technology and traces historical advances alongside the latest breakthroughs in battery science and future perspectives. This book serves as a beacon, bridging historical milestones with future goals. It thoroughly explores materials, including lithium-ion and sodium-ion, in a manner accessible to everyone. It lays a robust groundwork for innovators in energy storage, steering us towards a more sustainable tomorrow. This work informs and connects readers to the evolving narrative of battery technology.
Renewable and Clean Energy Systems Based on Advanced Nanomaterials: Basis, Preparation and Applications describes the fundamental aspects of a diverse range of nanomaterials used in the fields of renewable and clean energy. Various methods of preparing several different nanomaterials for green energy systems, such as advanced nanomaterials for solar cells, mixed metal oxide-based nanomaterials for hydrogen storage, and active nanomaterials for Li ion batteries are presented along with their advantages, disadvantages, and applications. Chapters also discuss novel methods of power analysis, frequency regulation methods, practical applications of solar panels, economic efficiency of solar energy, solar physics, and much more.This is a valuable resource on the basic science, preparation methods, and practical applications of advanced nanomaterials for green energy systems. - Features recent advances on nanomaterials preparation methods and their applications in photovoltaic technology - Discusses sustainable strategies for producing large-scale nanomaterials, focusing on preparation techniques that are cost-effective and eco-friendly - Reviews the efficiency of nanomaterials used in solar energy storage and conversion
As the global community confronts challenges in energy, environment, health, agriculture, industry, and construction, the significance of sustainable materials becomes paramount. The looming specter of resource depletion necessitates a paradigm shift, urging researchers and engineers to anticipate future needs and forge materials that align with evolving requirements. Next Generation Materials for Sustainable Engineering underscores the urgency of conserving resources and provides a blueprint for achieving this through judicious and sustainable use. From polymers to alloys, nanocomposites to biomaterials, this book traverses the expansive landscape of materials, deciphering their structures and properties with an eye toward sustainability. The relentless pursuit of innovation in synthesis protocols takes center stage, unveiling pathways to creating novel materials. The chapters dedicated to specific material applications, such as spintronics, nanowires, phase change materials, and nanocomposites, offer a detailed panorama of the latest advancements. This book bridges the gap between theoretical understanding and practical applications by exploring materials for renewable energy, electronic devices, artificial photosynthesis, lithium-sulfur batteries, supercapacitors, and biomedical applications. The book serves as a beacon for academicians, researchers, and material scientists, guiding them through state-of-the-art developments, emerging trends, and challenges in material science and engineering.
Model predictive control (MPC) is a method for controlling a process while satisfying a set of constraints. The use of MPC for controlling power systems has been gaining traction in recent years. This work presents the use of MPC for distributed renewable power generation in microgrids.