Liquid Cooling of Electronic Devices by Single-Phase Convection offers the first comprehensive and in-depth coverage of liquid convection as it applies to state-of-the-art thermal management systems. In this book, Dr. Incropera culls ten years of research results, clarifies the physical mechanisms associated with single-phase convection in the context of electronic cooling, and provides working engineers with a solid foundation for the design and development of rational liquid cooling systems. For those involved in designing these products - mechanical and electrical engineers, electronic packaging engineers, technical staff, and others - this book provides an invaluable road map to meet the challenge.

This book is a comprehensive guide on emerging cooling technologies for processors in microelectronics. It covers various topics such as chip-embedded two-phase cooling, monolithic microfluidic cooling, numerical modeling, and advances in materials engineering for conduction-limited direct contact cooling, with a goal to remedy high heat flux issues.The book also discusses the co-design of thermal and electromagnetic properties for the development of light and ultra-high efficiency electric motors. It provides an in-depth analysis of the scaling limits, challenges, and opportunities in embedded cooling, including high power RF amplifiers and self-emissive and liquid crystal displays. Its analysis of emerging cooling technologies provides a roadmap for the future of cooling technology in microelectronics.This book is a good starting point for the electrical and thermal engineers, as well as MS and PhD students, interested in understanding and collaboratively tackling the complex and multidisciplinary field of microelectronics device (embedded) cooling. A basic knowledge of heat conduction and convection is required.

Featuring contributions from the renowned researchers and academicians in the field, this book covers key conventional and emerging cooling techniques and coolants for electronics cooling. It includes following thematic topics: - Cooling approaches and coolants - Boiling and phase change-based technologies - Heat pipes-based cooling - Microchannels cooling systems - Heat loop cooling technology - Nanofluids as coolants - Theoretical development for the junction temperature of package chips. This book is intended to be a reference source and guide to researchers, engineers, postgraduate students, and academicians in the fields of thermal management and cooling technologies as well as for people in the electronics and semiconductors industries.

Electronic technology is developing rapidly and, with it, the problems associated with the cooling of microelectronic equipment are becoming increasingly complex. So much so that it is necessary for experts in the fluid and thermal sciences to become involved with the cooling problem. Such thoughts as these led to an approach to leading specialists with a request to contribute to the present book. Cooling of Electronic Systems presents the technical progress achieved in the fundamentals of the thermal management of electronic systems and thermal strategies for the design of microelectronic equipment. The book starts with an introduction to the cooling of electronic systems, involving such topics as trends in computer system cooling, the cooling of high performance computers, thermal design of microelectronic components, natural and forced convection cooling, cooling by impinging air and liquid jets, thermal control systems for high speed computers, together with a detailed review of advances in manufacturing and assembly technology. Following this, practical methods for the determination of the parameters required for the thermal analysis of electronic systems and the accurate prediction of temperature in consumer electronics. Cooling of Electronic Systems is currently the most up-to-date book on the thermal management of electronic and microelectronic equipment, and the subject is presented by eminent scientists and experts in the field. Vital reading for all designers of modern, high-speed computers.

This handbook systematically collects the latest scientific and technological knowledge on liquid metals obtained so far in this cutting edge frontier. Conventional materials such as metals, polymers, composites, ceramics and naturally derived matters, may not perform well when facing certain technological challenges. At around room temperature, most of such materials mainly stay at solid state and are often difficult to shape due to their high melting point. Meanwhile, although classical soft matters own good flexibility, their electrical conductivities including more behaviours appear not good enough which generally limited their utilizations. As a game-changing alternative, the room temperature liquid metal materials are quickly emerging as a new generation functional material which displayed many unconventional properties superior to traditional materials. Their outstanding versatile feature as “One material, diverse capabilities” is rather unique among existing materials and thus opens many exciting opportunities for scientific, technological and industrial developments. This handbook presents comprehensive reference information on liquid metal science and technology that are currently available. The major advancements as made before are collected and summarized. Representative liquid metal applications are illustrated. It helps readers obtain a comprehensive understanding of the technical progresses and fundamental discoveries in the frontier, and thus better explore and utilize liquid metal materials to address various challenging needs.

Together with turbulence, multiphase flow remains one of the most challenging areas of computational mechanics and experimental methods and numerous problems remain unsolved to date. Multiphase flows are found in all areas of technology, at all length scales and flow regimes. The fluids involved can be compressible or incompressible, linear or nonlinear. Because of the complexity of the problems, it is often essential to utilize advanced computational and experimental methods to solve the complex equations that describe them. Challenges in these simulations include modelling and tracking interfaces, dealing with multiple length scales, modelling nonlinear fluids, treating drop breakup and coalescence, characterizing phase structures, and many others. Experimental techniques, although expensive and difficult to perform, are essential to validate models. This book contains papers presented at the Fifth International Conference on Computational Methods in Multiphase Flow, which are grouped into the following topics: Multiphase Flow Simulation; Interaction of Gas, Liquids and Solids; Turbulent Flow; Environmental Multiphase Flow; Bubble and Drop Dynamics; Flow in Porous Media; Heat Transfer; Image Processing; Interfacial Behaviour.

This book celebrates a few examples of the many women who have advanced the field of nanotechnology. The book opens with an overview of the field, illuminating how nanotechnology is opening the door to manipulating matter on a scale one billionth of a meter. Then the use of nanotechnology to improve science and scientific literacy is discussed, and strategies for incorporating nanotechnology in K-12 education are presented. Next, an array of female scientists provide technical descriptions of how their work is impacting their respective areas. Topics include applications in the energy, electronics, water, communication and health care sectors, among others. The book closes with a historical perspective on the U.S. National Nanotechnology Initiative and future prospects for nanotechnology. This book provides the opportunity to appreciate some of the key advancements made by women engineers in nanotechnology and to become inspired by the ingenuity and creativity, collaborative nature, and altruistic inventiveness of women engineers. Includes contributions from leading female scientists in nanotechnology Highlights topics in nanotechnology ranging from health care, to sensors, to alternative energy, to clean water, to nanoelectronics Presents an opportunity to learn about the breadth, depth and impact of the field of nanotechnology and women’s important contributions to it