Storage and conversion are critical components of important energy-related technologies. "Advanced Batteries: Materials Science Aspects" employs materials science concepts and tools to describe the critical features that control the behavior of advanced electrochemical storage systems. This volume focuses on the basic phenomena that determine the properties of the components, i.e. electrodes and electrolytes, of advanced systems, as well as experimental methods used to study their critical parameters. This unique materials science approach utilizes concepts and methodologies different from those typical in electrochemical texts, offering a fresh, fundamental and tutorial perspective of advanced battery systems. Graduate students, scientists and engineers interested in electrochemical energy storage and conversion will find "Advanced Batteries: Materials Science Aspects" a valuable reference.
Energy Storage explains the underlying scientific and engineering fundamentals of all major energy storage methods. These include the storage of energy as heat, in phase transitions and reversible chemical reactions, and in organic fuels and hydrogen, as well as in mechanical, electrostatic and magnetic systems. Updated coverage of electrochemical storage systems considers exciting developments in materials and methods for applications such as rapid short-term storage in hybrid and intermittent energy generation systems, and battery optimization for increasingly prevalent EV and stop-start automotive technologies. This nuanced coverage of cutting-edge advances is unique in that it does not require prior knowledge of electrochemistry. Traditional and emerging battery systems are explained, including lithium, flow and liquid batteries. Energy Storage provides a comprehensive overview of the concepts, principles and practice of energy storage that is useful to both students and professionals.
Introduction Energy is necessary for a number of reasons, the most basic and obvious involve the preparation of food and the provision of heat to make life comfortable, or at least, bearable. Subsequently, a wide range of technological uses of energy have emerged and been developed, so that the availability of energy has become a central issue in society. The easiest way to acquire useful energy is to simply ?nd it as wood or a hydrocarbon fossil fuel in nature. But it has often been found to be advantageous to convert what is simply available in nature into more useful forms, and the processing and conversion of raw materials, especially petrochemicals have become a very large industry. Wood Wood has been used to provide heat for a great many years. In some cases, it can be acquired as needed by foraging, or cutting, followed by simple collection. When it is abundant there is relatively little need for it to be stored. However, many societies have found it desirable to collect more wood than is immediately needed during warm periods during the year, and to store it up for use in the winter, when the needs are greater, or its collection is not so convenient. One can still see this in some locations, such as the more remote communities in the Alps, for example. One might think of this as the oldest and simplest example of energy storage.
Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- List of Tables -- 1 Introduction -- 2 The Socio-Economics of Networks -- 3 Space, Place and Policy Intervention -- 4 TECs and their Network Policies - The Early Years -- 5 Business Co-operation and TECs - Developing Networks -- 6 The Evolution of TECs and Networked Economic Development -- 7 Evaluating Network Policies -- 8 The Success and Failure of Implanted Networks -- 9 Conclusions -- References -- Index
Introduction Energy is necessary for a number of reasons, the most basic and obvious involve the preparation of food and the provision of heat to make life comfortable, or at least, bearable. Subsequently, a wide range of technological uses of energy have emerged and been developed, so that the availability of energy has become a central issue in society. The easiest way to acquire useful energy is to simply ?nd it as wood or a hydrocarbon fossil fuel in nature. But it has often been found to be advantageous to convert what is simply available in nature into more useful forms, and the processing and conversion of raw materials, especially petrochemicals have become a very large industry. Wood Wood has been used to provide heat for a great many years. In some cases, it can be acquired as needed by foraging, or cutting, followed by simple collection. When it is abundant there is relatively little need for it to be stored. However, many societies have found it desirable to collect more wood than is immediately needed during warm periods during the year, and to store it up for use in the winter, when the needs are greater, or its collection is not so convenient. One can still see this in some locations, such as the more remote communities in the Alps, for example. One might think of this as the oldest and simplest example of energy storage.
Written by a noted historian of science, this in-depth account traces how Watson and Crick achieved one of science's most dramatic feats: their 1953 discovery of the molecular structure of DNA.
In 1789, Horace Walpole defined serendipity as "making discoveries by accident"; it was through acceptance of this inherent chaos that some of history's most influential advances were made, such as Alfred Nobel and dynamite, Marie Curie and radium, and Alexander Fleming and penicillin. Usually chaotic-serendipitous observations are either not recognized by hypothesis-driven researchers or, if observed, rejected by them. Fortunately, the Naval Blood Research Laboratory (NBRL) has been able to embrace important chaotic and serendipitous observations that were critical to the productivity of the laboratory. As former director of the NBRL, C. Robert Valeri, MD, spent forty-five years exploring hematocrit, bleeding time, and nonsurgical blood loss, as well as other blood-related advances used to treat military and civilian personnel. In this volume, he reviews those advances and recalls his time at the NBRL.
In this shocking true account, Mark Fisher, a nineteen-year-old college student and star football player, unaware of the dark side of New York City night life, attends a party with an attractive stranger, which leads to his brutal murder at the hands of a group of wannabe gangsters. Original.
Eine in sich geschlossene, umfassende Einführung in die Grundlagen der Grenzflächenphänomene und ihrer Anwendung auf Prozesse und Produktdesign - geschrieben für Ingenieure aus Chemie, Elektronik und Biomedizin. Zwischenmolekulare Wechselwirkungen an der Grenzfläche werden ausführlich behandelt; Eigenschaften, Verarbeitung und Verhalten fluider Grenzflächen werden ebenso diskutiert wie Ober- und Grenzflächenmerkmale fester Stoffe. Dieses Buch ist relevant für den Praktiker in der Industrie, stellt aber gleichzeitig eine wertvolle Hilfe für Lehrkräfte ingenieurwissenschaftlicher Fachrichtungen bei der Ausbildungsplanung dar.
Multiple killings by serial or spree killers and the mass violence seen in war crimes and other atrocities have typically been understood as discrete category types, which can foster the view that there are fundamentally different kinds of human beings, including "deviants" who are born evil and innately given to sadism or a callous lack of empathy. In contrast, this book considers the violence of these "deviants" in terms of larger questions about human violence. Therefore, in addition to describing the life histories of a sample of individual serial and spree murderers, the book includes analysis of macro-level phenomena such as genocide, mass rape and killing, and torture occurring under conditions of war, state authorization, or political upheaval. The chief claim of the book is that, given the "right" combination of factors occurring at different levels of analysis, virtually anyone can emerge as a killer or perpetrator of atrocities. While it is crucial to understand individual killers in terms of the details of their biographies, it is equally crucial to understand political atrocities in terms of the details of their histories; and to see that persons and groups are always the product of complexly interacting assemblage processes.
“The best biography ever written about an American sports figure.” —Sports Illustrated Nearly a century has passed since George Herman Ruth made his major league debut, and in that time millions of words have been used to describe baseball’s greatest hero. But for a man like the Babe, for whom the phrase “larger than life” seems to have been coined, those millions of words have created a mythologized legacy. Who was the real Babe Ruth? Relying on exhaustive research and interviews with teammates, family members, and friends, historian Robert W. Creamer separates fact from fiction and paints an honest and fascinating portrait of the slugger. This is the definitive biography of a man who was, in legend and in truth, the best who ever lived.
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