Modern technology depends heavily on advances in the electrochemical field, but this field may not be receiving the research attention and funding it needs. This new book addresses this issue. It reviews the status of current electrochemical knowledge, recommends areas of future research and development, identifies new technological opportunities in electrochemistry, delineates opportunities for interdisciplinary research, and outlines the socioeconomic impact of electrochemical advances.
This book titled "Recent Trend in Electrochemical Science and Technology" contains a selection of chapters focused on advanced methods used in the research area of electrochemical science and technologies; descriptions of electrochemical systems; processing of novel materials and mechanisms relevant for their operation. This book provides an overview on some of the recent development in electrochemical science and technology. Particular emphasis is given both to the theoretical and the experimental aspect of modern electrochemistry. Since it was impossible to cover the rich diversity of electrochemical techniques and applications in a single issue, the focus is on the recent trends and achievements related to electrochemical science and technology.
In this topical volume, the authors provide in-depth coverage of the vital relationship between electrochemistry and the morphology of thin films and surfaces. Clearly divided into four major sections, the book covers nanoscale dielectric films for electronic devices, superconformal film growth, electrocatalytic properties of transition metal macrocycles, and the use of synchrotron techniques in electrochemistry. All the chapters offer a concise introduction to the relevant topic, as well as supplying numerous references for easy access to further reading and the original literature. The result is must-have reading for electrochemists, physical and surface chemists and physicists, as well as materials scientists and engineers active in the field of spectroscopic methods in electrochemistry.
Papers in this volume are from the 199th ECS Meeting, held in Washington, DC, Spring 2001. Morphology evolution encompasses electrochemical processing in ULSI fabrication, shape evolution, growth habit, and microstructure of electrodeposits. The most prominent example at present is the electrochemical deposition of copper for ULSI interconnects. Many other electrochemical processes at various stages of emergence and development hold promise for the electronics industry and beyond.
This book originated out of the papers presented at the special symposium, "Electrochemistry in Transition-From the 20th to the 21st Century," scheduled by the Division of Colloid and Surface Science during the American Chemical Society meeting in Toronto. The symposium was in honor of Professor J. O'M. Bockris, who received the ACS award on "The Chemistry of Contemporary Technological Problems" (sponsored by Mobay Corporation) during this meeting and who also reached his 65th birthday in the same year. The symposium was of a multidisciplinary nature and encompassed the fields of theoretical and experimental elec trochemistry, surface science, spectroscopy, and electrochemical technology. The symposium also had an international flavor in that the participants represented several countries Australia, Belgium, Canada, Chile, England, Japan, Korea, the Netherlands, Poland, Switzer land, Venezuela, Yugoslavia, and the United States. The symposium was graciously sponsored by the ACS (Petroleum Research Fund and Division of Colloid and Surface Science), Alcan International, Dow Chemical Company, EG&G, Electrolyzer Corporation, Exxon, General Electric Company, IBM, Institute of Gas Technology, International Association of Hydrogen Energy, Johnson Matthey, Inc. , Kerr-McGee Corporation, Medtronics, and Texas A&M University (Center for Electrochemical Systems and Hydrogen Research and the Hampton Robinson Fund). The "theme" of the papers presented at the symposium covered not only significant contributions made to electrochemistry in the twentieth century, but also "New Horizons in Electrochemistry" for the twenty-first century. Thus, the scientists who presented papers were invited to contribute chapters to this book, having the same titles as the symposium.
This book examines the metal/solution interface with the electrochemical quartz crystal microbalance, exploring electrostatic adsorption, metal deposition, and roughness. It explores the indirect laser-induced temperature-jump method for characterizing fast interfacial electron transfer.
Advances in materials science and engineering have paved the way for the development of new and more capable sensors. Drawing upon case studies from manufacturing and structural monitoring and involving chemical and long wave-length infrared sensors, this book suggests an approach that frames the relevant technical issues in such a way as to expedite the consideration of new and novel sensor materials. It enables a multidisciplinary approach for identifying opportunities and making realistic assessments of technical risk and could be used to guide relevant research and development in sensor technologies.
This book focuses on nanotechnology for the preparation of metal oxide–based carbon nanocomposite materials for environmental remediation. It analyses the use of nanomaterials for water, soil, and air solutions, emphasizing the environmental risks of pollution. It further explores how magnetic and activated carbon nanomaterials are being used for a sustainable environmental protection of water and soil, and detection of harmful gases. The status and major challenges of using carbon-based nanomaterials on a large scale are explained, supported by relevant case studies. Features: Exhaustively covers nanotechnology, metal oxide–carbon nanocomposites and their application in soil, water, and air treatments Explores pollutants nano-sensing and their remediation towards environmental safety Includes economics analysis and environmental aspects of metal oxide materials Describes why properties of oxide carbon–based nanomaterials are useful for environmental applications Discusses current case studies of remediation technologies This book is aimed at graduate students and researchers in nanotechnology, environmental technology, and remediation.
