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The problem of storing hydrogen safely and effectively is one of the major technological barriers currently preventing the widespread adoption of hydrogen as an energy carrier and the subsequent transition to a so-called hydrogen economy. Practical issues with the storage of hydrogen in both gas and liquid form appear to make reversible solid state hydrogen storage the most promising potential solution. Hydrogen Storage Materials addresses the characterisation of the hydrogen storage properties of the materials that are currently being considered for this purpose. The background to the topic is introduced, along with the various types of materials that are currently under investigation, including nanostructured interstitial and complex hydrides, and porous materials, such as metal-organic frameworks and microporous organic polymers. The main features of Hydrogen Storage Materials include: an overview of the different types of hydrogen storage materials and the properties that are of interest for their practical use; descriptions of the gas sorption measurement methods used to determine these properties, and the complementary techniques that can be used to help corroborate hydrogen uptake data; and extensive coverage of the practical considerations for accurate hydrogen sorption measurement that drive both instrument design and the development of experimental methodology. Hydrogen Storage Materials provides an up-to-date overview of the topic for experienced researchers, while including enough introductory material to serve as a useful, practical introduction for newcomers to the field.
Hydrogen --- Storage. --- Nonmetals --- Renewable energy sources. --- Renewable and Green Energy. --- Energy Systems. --- Energy Storage. --- Alternate energy sources --- Alternative energy sources --- Energy sources, Renewable --- Sustainable energy sources --- Power resources --- Renewable natural resources --- Agriculture and energy --- Renewable energy resources. --- Energy systems. --- Energy storage. --- Storage of energy --- Force and energy --- Power (Mechanics) --- Flywheels --- Pulsed power systems
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Le stockage et la conversion de l’énergie sont un des grands défis scientifiques des prochaines décennies et un enjeu environnemental majeur. Quels nouveaux matériaux vont permettre de fabriquer des batteries plus efficaces et plus « propres » ? Jean-Marie Tarascon fait le point sur ces questions qui concernent notre avenir et celui de la planète. Il présente notamment les technologies à ions Lithium, l’apport des nanaotechnologies, et les recherches visant à l’élaboration des matériaux par des méthodes « bio-inspirées » : l’utilisation des matériaux d'électrodes provenant de la biomasse et obtenues par « chimie verte ». The storage and conversion of energy represents one of the major scientific challenges for coming decades with high stakes for the environment. Which new materials will enable the construction of more efficient and “cleaner” batteries? Jean-Marie Tarascon takes stock of these questions with their implications for our future and that of the planet. He notably discusses lithium-ion technology, the contribution of nanotechnologies and current research into using bio-inspired methods to develop material such as electrode material obtained from the biomass by scientists working in the field of “green chemistry”.
Energy storage --- Electric power production from chemical action --- Sustainable engineering --- Lithium ion batteries --- Mechanical Engineering --- Engineering & Applied Sciences --- Mechanical Engineering - General --- Environmental aspects --- Cells, Lithium ion --- Electrochemical cells, Lithium ion --- LIBs (Lithium ion batteries) --- Li-ion batteries --- Lithium ion cells --- Lithium ion electrochemical cells --- Engineering sustainability --- Green engineering --- Storage of energy --- Storage batteries --- Engineering --- Green technology --- Environmental engineering --- Direct energy conversion --- Force and energy --- Power (Mechanics) --- Flywheels --- Pulsed power systems --- chimie verte --- développement durable --- énergie --- nanotechnologies --- environnement --- batteries à ions lithium
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Iron Phosphate Materials as Cathodes for Lithium Batteries describes the synthesis and the chemical–physical characteristics of iron phosphates, and presents methods of making LiFePO4 a suitable cathode material for lithium-ion batteries. The author studies carbon’s ability to increase conductivity and to decrease material grain size, as well as investigating the electrochemical behaviour of the materials obtained. Iron Phosphate Materials as Cathodes for Lithium Batteries also proposes a model to explain lithium insertion/extraction in LiFePO4 and to predict voltage profiles at various discharge rates. Iron Phosphate Materials as Cathodes for Lithium Batteries is written for postgraduate students and researchers in electrochemistry, R&D professionals and experts in electrochemical storage.
Electric batteries. --- Fuel cells. --- Lithium cells. --- Solar energy. --- Lithium cells --- Cathodes --- Iron --- Electrical & Computer Engineering --- Engineering & Applied Sciences --- Electrical Engineering --- Electrometallurgy --- Cathodes. --- Electrometallurgy. --- Batteries, Lithium --- Cells, Lithium --- Engineering. --- Energy storage. --- Electrochemistry. --- Electric power production. --- Metals. --- Energy Technology. --- Metallic Materials. --- Energy Storage. --- Cathode rays --- Electrodes --- Electron tubes --- Electric batteries --- Materials. --- Chemistry. --- Energy Systems. --- Physical sciences --- Engineering --- Engineering materials --- Industrial materials --- Engineering design --- Manufacturing processes --- Materials --- Energy systems. --- Metallic elements --- Chemical elements --- Ores --- Metallurgy --- Storage of energy --- Force and energy --- Power (Mechanics) --- Flywheels --- Pulsed power systems --- Chemistry, Physical and theoretical
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S.C. Singhal and X.-D. Zhou: Solid Oxide Fuel Cells.- H. Wang and H.D. Abruña: Electrocatalysis of Direct Alcohol Fuel Cells: Quantitative DEMS Studies.- J. Benziger, A. Bocarsly, M.J. Cheah, P.Majsztrik, B. Satterfield and Q. Zhao: Mechanical and Transport Properties of Nafion: Effects of Temperature and Water Activity.- S. Sachdeva, J. A. Turner, J.L. Horana and A. M. Herring: The Use of Heteropoly Acids in Proton Exchange Fuel Cells.- M. T. Kelly: Perspective on the Storage of Hydrogen: Past and Future.-.
Fuel cells --- Hydrogen as fuel --- Inorganic Chemicals --- Environment --- Elements --- Gases --- Organic Chemicals --- Natural Science Disciplines --- Disciplines and Occupations --- Chemicals and Drugs --- Environment and Public Health --- Health Care --- Energy-Generating Resources --- Hydrogen --- Alcohols --- Chemistry --- Electrical & Computer Engineering --- Engineering & Applied Sciences --- Physical Sciences & Mathematics --- Electrical Engineering --- Inorganic Chemistry --- Physical & Theoretical Chemistry --- Fuel cells. --- Energy storage. --- Hydrogen as fuel. --- Hydrogen energy --- Storage of energy --- Chemistry. --- Inorganic chemistry. --- Inorganic Chemistry. --- Fuel --- Force and energy --- Power (Mechanics) --- Flywheels --- Pulsed power systems --- Direct energy conversion --- Electric batteries --- Electric power production from chemical action --- Electrochemistry --- Chemistry, inorganic. --- Inorganic chemistry --- Inorganic compounds
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Second-Generation High-Temperature Superconducting Coils and Their Applications for Energy Storage addresses the practical electric power applications of high-temperature superconductors. It validates the concept of a prototype energy storage system using newly available 2G HTS conductors by investigating the process of building a complete system from the initial design to the final experiment. It begins with a clear introduction of the related background and then presents a comprehensive design of a superconducting energy storage system that can store maximum energy using a limited length of superconductors. The author has created a modeling environment for analysis of the system and also presents experimental results that are highly consistent with his theoretical calculations.
Engineering. --- High temperature superconductors. --- Magnetic energy storage. --- Thin films. --- Mechanical Engineering --- Engineering & Applied Sciences --- Mechanical Engineering - General --- Materials at high temperatures. --- Superconductors. --- Superconducting magnets. --- Energy storage. --- Superconductivity. --- Storage of energy --- Magnets, Superconducting --- Superconducting high-field magnets --- Superconducting materials --- Superconductive devices --- Renewable energy resources. --- Renewable energy sources. --- Alternate energy sources. --- Green energy industries. --- Renewable and Green Energy. --- Electric conductivity --- Critical currents --- Superfluidity --- Force and energy --- Power (Mechanics) --- Flywheels --- Pulsed power systems --- Electromagnets --- Superconductors --- Electric power --- Energy storage --- Superconducting magnets --- Cryoelectronics --- Electronics --- Solid state electronics --- High temperatures --- Materials --- Strength of materials --- Materials at low temperatures --- Alternate energy sources --- Alternative energy sources --- Energy sources, Renewable --- Sustainable energy sources --- Power resources --- Renewable natural resources --- Agriculture and energy
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Physics --- Materials --- Energy storage --- Photochemistry --- Fuel cells --- Thermoelectric materials --- Research --- Materials science research --- Publications périodiques. --- Technologie énergétique. --- Piles à combustible. --- Physicochemistry --- Engineering --- Civil Engineering --- Optics & Opto Electronics --- E-journals --- Light --- Photolysis (Chemistry) --- Storage of energy --- Chemical action --- Fuel cells. --- Materials. --- Research. --- Materials science research (Title) --- Electrical engineering --- Semiconductors --- Thermoelectricity --- Direct energy conversion --- Electric batteries --- Electric power production from chemical action --- Electrochemistry --- Chemistry, Physical and theoretical --- Force and energy --- Power (Mechanics) --- Flywheels --- Pulsed power systems --- Photochemical research --- Industrial materials --- Engineering design --- Manufacturing processes --- Materials science research (Uniform Title) --- Technologie énergétique --- fuel cell. --- energy technology. --- energiteknologi --- tecnologia energetica --- energiatehnoloogia --- energiatechnológia --- energetická technológia --- energiateknologia --- енергийна технология --- energiteknik --- ενεργειακή τεχνολογία --- energetická technologie --- technologie énergétique --- teknoloġija enerġetika --- energetska tehnologija --- енергетска технологија --- tecnología energética --- Energietechnologie --- teknologji e energjisë --- energotehnoloģija --- technologia energetyczna --- tecnologia energética --- energetikos technologija --- energietechnologie --- tehnologie energetică --- teicneolaíocht fuinnimh --- energetische techniek --- tehnologija energije --- Energietechnik --- energetikai technológia --- energetická technika --- technique énergétique --- tüzelőanyag-cella --- горивна ћелија --- горивна ќелија --- brandstofcel --- bateri --- горивна клетка --- Brennstoffzelle --- dispozitiv de conversie a energiei chimice --- ċellula tal-fjuwil --- kütuseelement --- kurināmā elements --- breosla-chill --- gorivna celica --- pila de combustible --- bränslecell --- pile à combustible --- brændselscelle --- kuro elementas --- στοιχεία καυσίμου --- ogniwo paliwowe --- pilha a combustível --- goriva ćelija --- pila a combustibile --- palivový článek --- palivový článok --- polttokenno --- degalų elementas --- батерија на гориво --- агрегат --- pilha redox --- brændstofcelle
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