This book presents recent advances in experimental and theoretical research on energy materials, focusing on materials that can potentially be used in the production of solar cells, hydrogen and energy storage devices. It discusses in detail the latest synthetic methods, processes, characterization methods and applications of materials like perovskite materials, metal sulfides, nanomaterials, and two-dimensional, transition metal dichalcogenides.
Discusses a wide range of material types, such as nanomaterials, carbonaceous electrocatalysts and electrolytes, thin films, phase change materials, 2D energy materials, triboelectric materials, and membrane materials Describes such applications as flexible energy storage devices, sensors, energy storage batteries, fuel and solar cells, photocatalytic wastewater treatment, and more Aimed at researchers and technologists working to solve alternative energy issues
This book highlights progress towards the capture, storage, and utilization of energy through the development of advanced materials and systems based on abundant elements, materials, and commodities. Energy is critical to human sustainability and a global-scale deployment of renewable energy systems will be required. Hence, the chapters integrate the fundamental aspects that enable the technical advancements in detail, along with an emphasis on the need for highly sustainable materials to enable real impact for humankind: To determine innovation of energy capture and storage through characterizations of materials in areas of electrical generation and electrical storage systems; To demonstrate better performance, economic and environmental advantages than the current state of the art; To define new chemistries and materials for innovations in energy density design through lower operational temperatures, improve safety, expanding operational voltage, battery durability lifetimes, and reduce system costs. Advances critical technical and commercial objectives for novel high energy density materials; Evaluates operational material models for optimizing energy capture that are integrated by configurations as a system; Illustrates utilization of material life cycle assessment for high energy outputs generators for sustainable materials.
Includes details of the fundamental phenomenological theories of solar cells, Li ion/ Li-air/Li-S batteries, fuel cells and their energy storage mechanisms. Discusses properties of various energy materials in addition to their device operation and evaluation. Includes details of the fundamental phenomenological theories of solar cells, Li ion/ Li-air/Li-S batteries, fuel cells and their energy storage mechanisms Discusses properties of various energy materials in addition to their device operation and evaluation
This book presents recent advances in experimental and theoretical research on energy materials, focusing on materials that can potentially be used in the production of solar cells, hydrogen and energy storage devices. It discusses in detail the latest synthetic methods, processes, characterization methods and applications of materials like perovskite materials, metal sulfides, nanomaterials, and two-dimensional, transition metal dichalcogenides.
Energy Materials: A Short Introduction to Functional Materials for Energy Conversion and Storage provides readers with an accessible overview of the functional materials currently employed or investigated for energy provision, conversion, and storage. Rather than exploring the physical and chemical basics of energy conversion and storage, this book focuses on the various materials used in this field with simple explanations of their design principles, specific functionality, and quantitative figures of merit. It is suited for advanced undergraduate and graduate students studying energy and energy materials in physics, material science, engineering, and chemistry courses, as well as scientists starting their research in the field of functional materials for energy applications. Key Features: Provides an accessible introduction to complex subjects in simple terms with pedagogical features to enhance learning Contains the latest developments in this exciting and growing area Discusses examples from modern high-impact research and applications
This book presents the latest advances in thermal energy storage development at both the materials and systems level. It covers various fields of application, including domestic, industrial and transport, as well as diverse technologies, such as sensible, latent and thermochemical. The contributors introduce readers to the main performance indicators for thermal storage systems, and discuss thermal energy storage (TES) technologies that can be used to improve the efficiency of energy systems and increase the share of renewable energy sources in numerous fields of application. In addition to the latest advances, the authors discuss the development and characterization of advanced materials and systems for sensible, latent and thermochemical TES, as well as the TES market and practical applications. They also report on and assess the feasibility of uniform characterization protocols and main performance indicators, compared to previous attempts to be found in the literature. The book will help to increase awareness of thermal energy storage technologies in both the academic and industrial sectors, while also providing experts new tools to achieve a uniform approach to thermal energy storage characterization methods. It will also be of interest to all students and researchers seeking an introduction to recent innovations in TES technologies.
Innovation through specific and rational design and functionalization has led to the development of a wide range of mesoporous materials with varying morphologies (hexagonal, cubic, rod-like), structures (silicates, carbons, metal oxides), and unique functionalities (doping, acid functionalization) that currently makes this field one of the most exciting in materials science and energy applications. This book focuses primarily on the rapid progress in their application in energy conversion and storage technologies, including supercapacitor, Li-ion battery, fuel cells, solar cells, and photocatalysis (water splitting) and will serve as a valuable reference for researchers in the field
The world is currently facing the urgent and demanding challenges of saving and utilizing energy as efficiently as possible. Materials science, where chemistry meets physics, has garnered a great deal of attention because of its versatile techniques for designing and producing new, desired materials enabling energy storage and conversion. This book is a comprehensive survey of the research on such materials. Unlike a monograph or a review book, it covers a wide variety of compounds, details diverse study methodologies, and spans different scientific fields. It contains cutting-edge research in chemistry and physics from the interdisciplinary team of Ehime University (Japan), the members of which are currently broadening the horizon of materials sciences through their own ideas, tailored equipment, and state-of-the-art techniques. Edited by Toshio Naito, a prominent materials scientist, this book will appeal to anyone interested in solid-state chemistry, organic and inorganic semiconductors, low-temperature physics, or the development of functional materials, including advanced undergraduate- and graduate-level students of solid-state properties and researchers in metal-complex science, materials science, chemistry, and physics, especially those with an interest in (semi)conducting and/or magnetic materials for energy storage and conversion.
The role of materials engineering is to provide the much needed support in the development of photovoltaic devices with the new and fundamental researches on novel energy materials with tailor-made photonic properties. "Advanced Energy Materials "has been designed to provide the state-of-the-art so that scientists can fully be informed of this vast multi-disciplinary approach. A good understanding on the excited state reactivity of photoactive materials helps to prepare new materials and molecules capable of absorbing light over a given wavelength range and using it for driving electron transfer. Scientifically and technologically well-equipped materials science has explored the possibilities of developing and optimizing the charge separation in the light-harvesting architectures, however it is yet to bear fruit due to the difficulty of transportation of electrons and holes to the corresponding electrodes. Modeling charge mobility in semiconductors is complicated due to the presence of bulk heterogeneity in the structure. The understanding of the interface between the metal electrode and the active materials, where charge collection takes place, is even more intriguing. In this book, the contributors have highlighted and provide in-depth detail of the key features that enable scientists to design new energy materials for the vast landscape of solar energy conversion as well as the materials processing and characterizations.
