Sir Horace Lamb (1849 1934) the British mathematician, wrote a number of influential works in classical physics. A pupil of Stokes and Clerk Maxwell, he taught for ten years as the first professor of mathematics at the University of Adelaide before returning to Britain to take up the post of professor of physics at the Victoria University of Manchester (where he had first studied mathematics at Owens College). As a teacher and writer his stated aim was clarity: 'somehow to make these dry bones live'. His Dynamics was first published in 1914 and the second edition, offered here, in 1923: it remained in print until the 1960s. It was intended as a sequel to his Statics (also reissued in this series), and like its predecessor is a textbook with examples.

Systems with mechanical degrees of freedom containing unstable objects are analysed in this monograph and algorithms for their control are developed, discussed, and numerically tested. This is achieved by identifying unstable modes of motion and using all available resources to suppress them. By using this approach the region of states from which a stable regime can be reached is maximised. The systems discussed in this book are models for pendula and vehicles and find applications in mechatronics, robotics as well as in mechanical and automotive engineering.

Our understanding of nature, and in particular of physics and the laws governing it, has changed radically since the days of the ancient Greek natural philosophers. This book explains how and why these changes occurred, through landmark experiments as well as theories that - for their time - were revolutionary. The presentation covers Mechanics, Optics, Electromagnetism, Thermodynamics, Relativity Theory, Atomic Physics and Quantum Physics. The book places emphasis on ideas and on a qualitative presentation, rather than on mathematics and equations. Thus, although primarily addressed to those who are studying or have studied science, it can also be read by non-specialists. The author concludes with a discussion of the evolution and organization of universities, from ancient times until today, and of the organization and dissemination of knowledge through scientific publications and conferences.

The central questions of this book are how technologies decline, how societies deal with technologies in decline, and how governance may be explicitly oriented towards parting with 'undesirable' technology. Surprisingly, these questions are fairly novel. Thus far, the dominant interest in historical, economic, sociological and political studies of technology has been to understand how novelty emerges, how innovation can open up new opportunities and how such processes may be supported. This innovation bias reflects how in the last centuries modern societies have embraced technology as a vehicle of progress. It is timely, however, to broaden the social study of technology and society: next to considering the rise of technologies, their fall should be addressed, too. Dealing with technologies in decline is an important challenge or our times, as socio-technical systems are increasingly part of the problems of climate change, biodiversity loss, social inequalities and geo-political tensions. This volume presents empirical studies of technologies in decline, as well as conceptual clarifications and theoretical deepening. Technologies in Decline presents an emerging research agenda for the study of technological decline, emphasising the need for a plurality of perspectives. Given that destabilisation and discontinuation are seen as a way to accelerate sustainability transitions, this book will be of interest to academics, students and policy makers researching and working in the areas of sustainability science and policy, economic geography, innovation studies, and science and technology studies.

Explores the link between universe, space exploration, and rocketry Discusses protection of Earth from asteroids, debris, and global warming Includes basic methodology to be adopted to design rockets for various specific applications Covers use of multi-objective optimization to realize a system and differences in design philosophies for satellite launch Examines material on environment protection of Earth

Summarizes current recycling processes, challenges, and perspectives. Offers a comprehensive review of current commercialized LIB recycling companies. Showcases an innovative closed-loop hydrometallurgical recycling process to recycle lithium cathode materials. Provides detailed modelling and economic analysis of several hydrometallurgical recycling processes. Features practical cases and data developed by the authors.

This book provides a general overview of several concepts of synchronization and brings together related approaches to secure communication in chaotic systems. This is achieved using a combination of analytic, algebraic, geometrical and asymptotical methods to tackle the dynamical feedback stabilization problem. In particular, differential-geometric and algebraic differential concepts reveal important structural properties of chaotic systems and serve as guide for the construction of design procedures for a wide variety of chaotic systems. The basic differential algebraic and geometric concepts are presented in the first few chapters in a novel way as design tools, together with selected experimental studies demonstrating their importance. The subsequent chapters treat recent applications. Written for graduate students in applied physical sciences, systems engineers, and applied mathematicians interested in synchronization of chaotic systems and in secure communications, this self-contained text requires only basic knowledge of integer ordinary and fractional ordinary differential equations. Design applications are illustrated with the help of several physical models of practical interest.

''The review articles in this series are invariably of a high standard, and those contained in the most recent volumes to appear (Volumes 14-16), are no exception.'' --- Journal of Plasma Physics, from a review of previous volumes The current volume includes chapters on the generation of noninductive current in a tokamak and resonance effects in oscillations of uneven flows of continuous media.

Collates the most relevant and up to date information on renewable energy systems in a user friendly format for undergraduate and high school students Focused on power production technologies from renewable energy sources. An introduction to how sources of renewable energy work; their advantages and drawbacks. Timely text with the need for fast adoption of renewable energy technologies around the world. Diverse audience including students with some scientific background such as final year in high school wanting to know more about combatting climate change.

This book explores the role and importance of interdisciplinary research in addressing key issues in climate and energy decision making. For over 30 years, an interdisciplinary team of faculty and students anchored at Carnegie Mellon University, joined by investigators and students from a number of other collaborating institutions across North America, Europe, and Australia, have worked together to better understand the global changes that are being caused by both human activities and natural causes. This book tells the story of their successful interdisciplinary work. With each chapter written in the first person, the authors have three key objectives: (1) to document and provide an accessible account of how they have framed and addressed a range of the key problems that are posed by the human dimensions of global change; (2) to illustrate how investigators and graduate students have worked together productively across different disciplines and locations on common problems; and (3) to encourage funders and scholars across the world to undertake similar large- scale interdisciplinary research activities to meet the world's largest challenges. Exploring topics such as energy efficiency, public health, and climate adaptation, and with a final chapter dedicated to lessons learned, this innovative volume will be of great interest to students and scholars of climate change, energy transitions and environmental studies more broadly.

This is the first monograph dedicated entirely to problems of stability and chaotic behaviour in planetary systems and its subsystems. The author explores the three rapidly developing interplaying fields of resonant and chaotic dynamics of Hamiltonian systems, the dynamics of Solar system bodies, and the dynamics of exoplanetary systems. The necessary concepts, methods and tools used to study dynamical chaos (such as symplectic maps, Lyapunov exponents and timescales, chaotic diffusion rates, stability diagrams and charts) are described and then used to show in detail how the observed dynamical architectures arise in the Solar system (and its subsystems) and in exoplanetary systems. The book concentrates, in particular, on chaotic diffusion and clearing effects. The potential readership of this book includes scientists and students working in astrophysics, planetary science, celestial mechanics, and nonlinear dynamics.

Introduces evolution of nanoparticles in the electrochemical energy storage devices Provides step-by-step synthesis of nanoparticles Discusses different characterization methods (Structural, Electrical, Optical, and Thermal) Includes use of nanoparticles in various electrochemical devices Aims to bridge the gap between the material synthesis and the real application including Q&A in each chapter

1) Power electronics dominated power systems 2) Controlling of Power electronics converters 3) Understanding the control and stability of power converters 4) To Increase the hosting capacity of renewable generations in modern power systems 5) To familiar with applications of emerging technologies in the power electronics dominated power systems.

1) Power electronics dominated power systems 2) Controlling of Power electronics converters 3) Understanding the control and stability of power converters 4) To Increase the hosting capacity of renewable generations in modern power systems 5) To familiar with applications of emerging technologies in the power electronics dominated power systems.

Most photovoltaic (PV) installations utilise heavy conventional glass or polycarbonate panels, and even newly developed thin plastic or metal films for PV cell use may fracture during both construction and application. Textile fabrics, the most widespread flexible materials in everyday use, offer a solution to the need for lightweight, flexible solar PV generators. Solar Textiles: The Flexible Solution for Solar Power is about the incorporation and operation of solar cells on textile fabrics. The combination of textile manufacturing and solar PV cell technology opens up further avenues for both the textile and semiconductor industries. Thus, this book reflects the progressively increasing commercial interest in PV cell technology and the versatility that their integration in textiles provides. Discusses textiles as electrical substrates Explains the photovoltaic effect and associated parameters Offers special consideration of solar cells on textiles Compares fibres and fabrics and how to implement PV activity on a textile Describes manufacturing methods outside of semiconductor technology Includes applications open only to textiles This work is aimed at textile technologists, electronic engineers, solar technologists, civil engineers and designers in building fabrics and architecture.

This book focusses on various options of taking up ventures for starting entrepreneurship in small/large scale in the field of renewable energy technologies. The book covers the fundamentals of entrepreneurship, renewable energy resources, their technologies involved and applications along with financial evaluations. The book will cater to the needs of students, researchers, various stakeholders, entrepreneurs etc. by providing valuable information on renewable energy technologies and their applications in developing entrepreneurship and establishing enterprise at individual level, specifically focusing on low carbon technology for sustenance of environment which is becoming increasingly important.

Seismic assessment and earthquake-resistant design are essential applications of earthquake engineering for achieving seismic safety for buildings, bridges, infrastructure, and many other components of the built environment. The Endurance Time Method (ETM) is used for seismic analysis of simple and complex structural systems and civil engineering infrastructure as well as producing optimal and cost-effective structural and detail designs. ETM is a relatively new approach to seismic assessment and design of structures. It has developed into a versatile tool in the field, and its practical applications are expected to increase greatly in the near future.

This volume presents contributions describing the micro- and macro-behaviours, new existence and uniqueness theorems, the formulation of multi-scale problems, etc. and now it is time to ponder again the state of matter and to discuss new trends and applications. The main focus is directed on the following items - Modelling and simulation of materials with significant microstructure, - Generalized continua as a result of multi-scale models, - Multi-field actions on materials resulting in generalized material models, and - Comparison with discrete modelling approaches

This book explores an ongoing puzzle: why don't catastrophic events, such as oil shocks and nuclear meltdowns, always trigger transitions away from the energy technologies involved? Jennifer F. Sklarew examines how two key factors - shocks and stakeholder relationships - combine to influence energy system transitions, applying a case study of Japan's trajectory from the time of the 1970s oil crises through the period following the 2011 Fukushima Daiichi nuclear disaster. Examining the role of diverse stakeholders' resilience priorities, she focuses on how changes in stakeholder cooperation and clout respond to and are affected by these shocks, and how this combination of shocks and relationship changes shapes energy policies and policymaking. From Japan's narrative, the book derives unique and universal lessons for cooperation on innovation and energy system resilience applicable to communities and nations around the globe, including implications for transitions in the context of the COVID-19 pandemic. The book also places energy system resilience and innovation in the broader context of the food-energy-water-climate nexus. Building Resilient Energy Systems: Lessons from Japan will appeal to all levels of readers with an interest in energy policy, energy technologies and energy transitions: experts and specialists; academics and students; practitioners and policymakers.

This book explores an ongoing puzzle: why don't catastrophic events, such as oil shocks and nuclear meltdowns, always trigger transitions away from the energy technologies involved? Jennifer F. Sklarew examines how two key factors - shocks and stakeholder relationships - combine to influence energy system transitions, applying a case study of Japan's trajectory from the time of the 1970s oil crises through the period following the 2011 Fukushima Daiichi nuclear disaster. Examining the role of diverse stakeholders' resilience priorities, she focuses on how changes in stakeholder cooperation and clout respond to and are affected by these shocks, and how this combination of shocks and relationship changes shapes energy policies and policymaking. From Japan's narrative, the book derives unique and universal lessons for cooperation on innovation and energy system resilience applicable to communities and nations around the globe, including implications for transitions in the context of the COVID-19 pandemic. The book also places energy system resilience and innovation in the broader context of the food-energy-water-climate nexus. Building Resilient Energy Systems: Lessons from Japan will appeal to all levels of readers with an interest in energy policy, energy technologies and energy transitions: experts and specialists; academics and students; practitioners and policymakers.

This book provides the basis of simulating a nuclear plant, in understanding the knowledge of how such simulations help in assuring the safety of the plants, thereby protecting the public from accidents. It provides the reader with an in-depth knowledge about modeling the thermal and flow processes in a fast reactor and gives an idea about the different numerical solution methods. The text highlights the application of the simulation to typical sodium-cooled fast reactor. The book * Discusses mathematical modeling of the heat transfer process in a fast reactor cooled by sodium. * Compares different numerical techniques and brings out the best one for the solution of the models. * Provides a methodology of validation based on experiments. * Examines modeling and simulation aspects necessary for the safe design of a fast reactor. * Emphasizes plant dynamics aspects, which is important for relating the interaction between the components in the heat transport systems. * Discusses the application of the models to the design of a sodium-cooled fast reactor It will serve as an ideal reference text for senior undergraduate, graduate students, and academic researchers in the fields of nuclear engineering, mechanical engineering, and power cycle engineering.

* It provides detailed multi-phase models of system components along with PSCAD implementation and analysis * It provides a comprehensive reference of transient cases in power systems along with protective solutions. * The cases are not limited to classical transients such as lightning strikes and switchings but rather the book discusses transient cases that power system operators and engineers had to deal with such as ferroresonance in details accompanied by computer simulations. * The book contains a chapter on original materials related to transformer windings with induced traveling waves. This concept has not been explored in any of the books published in the area of transients.

Phasor Measurement Units and Wide Area Monitoring Systems presents complete coverage of phasor measurement units (PMUs), bringing together a rigorous academic approach and practical considerations on the implementation of PMUs to the power system. In addition, it includes a complete theory and practice of PMU technology development and implementation in power systems.

Offshore Wind Farms: Technologies, Design and Operation provides the latest information on offshore wind energy, one of Europe's most promising and quickly maturing industries, and a potentially huge untapped renewable energy source which could contribute significantly towards EU 20-20-20 renewable energy generation targets. It has been estimated that by 2030 Europe could have 150GW of offshore wind energy capacity, meeting 14% of our power demand. Offshore Wind Farms: Technologies, Design and Operation provides a comprehensive overview of the emerging technologies, design, and operation of offshore wind farms. Part One introduces offshore wind energy as well as offshore wind turbine siting with expert analysis of economics, wind resources, and remote sensing technologies. The second section provides an overview of offshore wind turbine materials and design, while part three outlines the integration of wind farms into power grids with insights to cabling and energy storage. The final section of the book details the installation and operation of offshore wind farms with chapters on condition monitoring and health and safety, amongst others.

Biohydrogen is a promising gaseous biofuel that has prospective applications in combined heat and power, for fuel cells, or as a precursor for chemicals production. Hydrogen can also be converted to liquid hydrocarbon fuels and value-added chemicals through catalytic thermochemical or through biocatalytic biological pathways. This book covers some the important recent advances in the production and utilization of biohydrogen and its solutions for clean fuel, waste management, waste valorization, reduced greenhouse gas emissions, and climate change mitigation. Biohydrogen: Developments and Prospects first covers the basic principles, benefits, and challenges concerning both the biological and thermochemical routes for biohydrogen production and then goes on to address topics such as biomass conversion to hydrogen through gasification with a focus on the process parameters, catalytic reforming technologies for hydrogen production concerning various feedstocks; the co-conversion of plastic wastes and biomass into biohydrogen through co-gasification technology; the effect of process parameters on syngas yields through co-gasification; fermentative hydrogen production technologies; the molecular mechanism of hydrogen production and enhancing the yield in hydrogen production by genetic and metabolic engineering; hydrogen production routes through microbial electrolysis; and much more. Key features: Helps to provide the most up-to-date information addressing solutions for clean fuel, waste management, waste valorization, reduced greenhouse gas emissions, and climate change mitigation Offers in-depth knowledge about recent developments on thermochemical methanation technologies and bioreactor and bioprocess design in anaerobic digestion technologies Discusses biotechnological interventions for metabolic engineering of microorganisms towards biohydrogen production Looks at gasification technologies and catalytic reforming technologies for hydrogen production Addressing both the fundamentals as well as advanced new technological research on biohydrogen production by focusing on recent global research with emphasis on the technological, environmental, socioeconomic, and techno-economic aspects, this volume will be a valuable resource for faculty and advanced students, chemical and biochemical engineers, bioprocess technologists, biochemists, environmental scientists and researchers as well as theoretical and applied statisticians and policymakers in this area.