The development, storage and comprehensive utilization of energy is an important subject concerned by scientists all over the world. Carbon capture and storage technology is one of the most effective mitigation technologies for global climate change, accurate understanding of the migration of multiphase fluids in reservoirs is crucial for reservoir stock evaluation and safety evaluation. Understanding Carbon Geologic Sequestration and Gas Hydrate from Molecular Simulation systematically introduces CO2 geological sequestration and gas hydrate at the molecular-scale, with research including interfacial properties of multiphase, multicomponent systems, hydrogen bonding properties, adsorption characteristics of CO2 / CH4 in the pore, kinetic properties of decomposition/nucleation/growth of gas hydrate, the influence of additives on gas hydrate growth dynamics, and hydrate prevention and control technology. This book focuses on research-based achievements and provides a comprehensive look at global progress in the field. Because there are limited resources available on carbon geologic sequestration technology and gas hydrate technology at the molecular level, the authors wrote this book to fill a gap in scientific literature and prompt further research. Distills learnings for fundamental and advanced knowledge of molecular simulation in carbon dioxide and gas hydrate storage Synthesizes knowledge about the development status of CGS technology and hydrate technology in the molecular field – tackling these technologies from a microscopic perspective Analyzes scientific problems related to CGS technology and hydrate technology based on molecular simulation methods Explores challenges relative to carbon dioxide and hydrate storage Provides hierarchical analysis combined with the authors’ own research-based case studies for enhanced comprehension and application
Since the end of Dennard scaling in the early 2000s, improving the energy efficiency of computation has been the main concern of the research community and industry. The large energy efficiency gap between general-purpose processors and application-specific integrated circuits (ASICs) motivates the exploration of customizable architectures, where one can adapt the architecture to the workload. In this Synthesis lecture, we present an overview and introduction of the recent developments on energy-efficient customizable architectures, including customizable cores and accelerators, on-chip memory customization, and interconnect optimization. In addition to a discussion of the general techniques and classification of different approaches used in each area, we also highlight and illustrate some of the most successful design examples in each category and discuss their impact on performance and energy efficiency. We hope that this work captures the state-of-the-art research and development on customizable architectures and serves as a useful reference basis for further research, design, and implementation for large-scale deployment in future computing systems.
Since the end of Dennard scaling in the early 2000s, improving the energy efficiency of computation has been the main concern of the research community and industry. The large energy efficiency gap between general-purpose processors and application-specific integrated circuits (ASICs) motivates the exploration of customizable architectures, where one can adapt the architecture to the workload. In this Synthesis lecture, we present an overview and introduction of the recent developments on energy-efficient customizable architectures, including customizable cores and accelerators, on-chip memory customization, and interconnect optimization. In addition to a discussion of the general techniques and classification of different approaches used in each area, we also highlight and illustrate some of the most successful design examples in each category and discuss their impact on performance and energy efficiency. We hope that this work captures the state-of-the-art research and development on customizable architectures and serves as a useful reference basis for further research, design, and implementation for large-scale deployment in future computing systems.
China is emerging as a new superpower in science and technology, reflected in the success of its spacecraft and high-velocity Maglev trains. While many seek to understand the rise of China as a technologically-based power, the Cultural Revolution of the 1960s may seem an unlikely era to explore for these insights. Despite the widespread verdict of the Great Proletarian Cultural Revolution as an unmitigated disaster for China, a number of recent scholars have called for re-examining Maoist science—both in China and in the West. At one time Western observers found much to admire in Chairman Mao's mass science, his egalitarian effort to take science out of the ivory tower and place it in the hands of the disenfranchised peasant, the loyal worker, and the patriot soldier. Chunjuan Nancy Wei and Darryl E. Brock have assembled a rich mix of talents and topics related to the fortunes and misfortunes of science, technology, and medicine in modern China, while tracing its roots to China's other great student revolution—the May Fourth Movement. Historians of science, political scientists, mathematicians, and others analyze how Maoist science served modern China in nationalism, socialism, and nation-building—and also where it failed the nation and the Chinese people. If the Cultural Revolution contributed to China's emerging space program and catalyzed modern malaria treatments based on Traditional Chinese Medicine, it also provided the origins of a science talent gap and the milieu from which a one-child policy would arise. Given the fundamental importance of China today, and of East Asia generally, it is imperative to have a better understanding of its most recent scientific history, but especially that history in a period of crisis and how that crisis was resolved. What is at issue here is not only the specific domain of the history of science, but the social and scientific policies of China generally as they developed and were applied prior to, during, and after the Cultural Revolution.
Ultrawideband (UWB) technology, positioned as the cutting edge of research and development, paves the way to meet the emerging demands set by broadband wireless applications, such as high-speed data transmission, medical imaging, short-range radars, electromagnetic testing, etc.This breathtaking resource builds upon the basics of UWB technology to provide a complete compilation of figures of merit along with a vital state-of-the-art of the different antenna alternatives that are to be employed according to the specific application. Without excessive recourse to mathematics, this volume emphasizes on the UWB antenna design and equips readers with practical prediction techniques based on simple formulas and models. The big picture of UWB antenna technology would not be complete without addressing its applications, and this will serve to provide consultants with key clues for market gap analysis. Containing over 150 supporting illustrations and figures, this comprehensive overview of UWB technology, antenna design and applications is a vital source of information and reference for R&D organizations, researchers, practitioners, consultants, RF professionals and communication engineers./a
China's Scientific Elite is a study of those scientists holding China's highest academic honour - membership of the Chinese Academy of Sciences. Having carried out extensive systematic data collection of CAS members Cao examines the social stratification system of the Chinese science community and the way in which politics and political interference has effected the stratification. The book then goes on to compare the Chinese system to the stratification of the US scientific elite. The conclusions are fascinating, not least because one national elite resides in a democratic liberal social system, and the other in an authoritarian social system.
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