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"Held May 2000 in Toronto, Canada, as part of the 197th meeting of the Electrochemical Society."--Pref.
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.
The papers in this issue describe the latest advances in fundamental and practical aspects of electrochemical processes for fabrication of microelectronic devices and related structures. Topics range from plating to etching, chips to packages, mechanisms to models, through-silicon vias to nanotubes, tin to ruthenium, capping to cooling, porous gold to porous alumina, probe-card springs to solder balls, electroless deposition to CMP, TFT-LCDs to magnetic nanowires and beyond.
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.
Nowadays, nanomaterials are attracting huge attentions not only from a basic research point of view but also for their potential applications. Since finding the structure-property-processing relationships can open new windows in the application of materials, the material characterizations play a crucial role in the research and development of materials science. The increasing demand for energy with the necessity to find alternative renewable and sustainable energy sources leads to the rapid growth in attention to energy materials. In this book, the results of some outstanding researches on synchrotron-based characterization of nanostructured materials related to energy applications are presented.
This volume in the "Advances in Electrochemical Sciences and Engineering" series focuses on problem-solving, illustrating how to translate basic science into engineering solutions. The book's concept is to bring together engineering solutions across the range of nano-bio-photo-micro applications, with each chapter co-authored by an academic and an industrial expert whose collaboration led to reusable methods that are relevant beyond their initial use. Examples of experimental and/or computational methods are used throughout to facilitate the task of moving atomistic-scale discoveries and understanding toward well-engineered products and processes based on electrochemical phenomena.
This issue covers papers relating to advanced semiconductor products that are true representatives of nanoelectronics have reached below 100 nm. Depending on the application, the nanosystem may consist of one or more of the following types of functional components: electronic, optical, magnetic, mechanical, biological, chemical, energy sources, and various types of sensing devices. As long as one or more of these functional devices is in 1-100 nm dimensions, the resultant system can be defined as nanosystem. Papers will be in all areas of dielectric issues in nanosystems. In addition to traditional areas of semiconductor processing and packaging of nanoelectronics, emphasis will be placed on areas where multifunctional device integration (through innovation in design, materials, and processing at the device and system levels) will lead to new applications of nanosystems.