A comprehensive presentation and analysis of properties and methods of formation of semiconducting silicides. Fundamental electronic, optical and transport properties of the silicides collected from recent publications will help readers choose their application in new generations of solid-state devices. A comprehensive presentation of thermodynamic and kinetic data is given in combination with their technical application, as is information on corresponding thin-film or bulk crystal formation techniques.
An up-to-date view of the various detector/emitter materials systems currently in use or being actively researched. The book is aimed at newcomers and those already working in the IR industry. It provides both an introductory text and a valuable overview of the entire field.
Rapid thermal processing has contributed to the development of single wafer cluster processing tools and other innovations in integrated circuit manufacturing environments. Borisenko and Hesketh review theoretical and experimental progress in the field, discussing a wide range of materials, processes, and conditions. They thoroughly cover the work of international investigators in the field.
This is the first book to provide guidance on the development and application of metal silicide technology as it emerges from the scientific to the prototype and manufacturing stages. Other key topics covered are fundamentals, present and future silicide technology for Si-based devices, and characterisation methods. Suitable for engineers and students in microelectronics.
Silicides were introduced into the technology of electronic devices some thirty years ago; since then, they have been continuously used to form both ohmic and rectifying contacts to silicon. Silicides are also important for other applications (thermoelectric devices and structural applications, such as jet engines), but it is not easy to find an updated reference containing both their basic properties, either chemical or physical, and the latest applications.The 16th Course of the International School of Solid State Physics, held in Erice (Italy) in the late spring of 1999, was intended to break artificial barriers between disciplines, and to gather people concerned with the properties and applications of silicides, regardless of the formal fields to which they belong, or of the practical goals they pursue. This book is therefore concerned with theory as well as applications, metallurgy as well as physics, and materials science as well as microelectronics.
VLSI Electronics: Microstructure Science, Volume 6: Materials and Process Characterization addresses the problem of how to apply a broad range of sophisticated materials characterization tools to materials and processes used for development and production of very large scale integration (VLSI) electronics. This book discusses the various characterization techniques, such as Auger spectroscopy, secondary ion mass spectroscopy, X-ray topography, transmission electron microscopy, and spreading resistance. The systematic approach to the technologies of VLSI electronic materials and device manufacture are also considered. This volume is beneficial to materials scientists, chemists, and engineers who are commissioned with the responsibility of developing and implementing the production of materials and devices to support the VLSI era.
This is the first definitive book on rapid thermal processing (RTP), an essential namufacturing technology for single-wafer processing in highly controlled environments. Written and edited by nine experts in the field, this book covers a range of topics for academics and engineers alike, moving from basic theory to advanced technology for wafer manufacturing. The book also provides new information on the suitability or RTP for thin film deposition, junction formation, silicides, epitaxy, and in situ processing. Complete discussions on equipment designs and comparisons between RTP and other processing approaches also make this book useful for supplemental information on silicon processing, VLSI processing, and integrated circuit engineering.
Metallic films play an important role in modern technologies such as integrated circuits, information storage, displays, sensors, and coatings. Metallic Films for Electronic, Optical and Magnetic Applications reviews the structure, processing and properties of metallic films. Part one explores the structure of metallic films using characterization methods such as x-ray diffraction and transmission electron microscopy. This part also encompasses the processing of metallic films, including structure formation during deposition and post-deposition reactions and phase transformations. Chapters in part two focus on the properties of metallic films, including mechanical, electrical, magnetic, optical, and thermal properties. Metallic Films for Electronic, Optical and Magnetic Applications is a technical resource for electronics components manufacturers, scientists, and engineers working in the semiconductor industry, product developers of sensors, displays, and other optoelectronic devices, and academics working in the field. - Explores the structure of metallic films using characterization methods such as x-ray diffraction and transmission electron microscopy - Discusses processing of metallic films, including structure formation during deposition and post-deposition reactions and phase transformations - Focuses on the properties of metallic films, including mechanical, electrical, magnetic, optical, and thermal properties
Atomic Layer Deposition can enable precise deposition of ultra-thin, highly conformal coatings over complex 3D topography, with controlled composition and properties for a wide range of applications.
