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Ion implantation is one of the key processing steps in silicon integrated circuit technology. Some integrated circuits require up to 17 implantation steps and circuits are seldom processed with less than 10 implantation steps. Controlled doping at controlled depths is an essential feature of implantation. Ion beam processing can also be used to improve corrosion resistance, to harden surfaces, to reduce wear and, in general, to improve materials properties. This book presents the physics and materials science of ion implantation and ion beam modification of materials. It covers ion-solid interactions used to predict ion ranges, ion straggling and lattice disorder. Also treated are shallow-junction formation and slicing silicon with hydrogen ion beams. Topics important for materials modification, such as ion-beam mixing, stresses, and sputtering, are also described.
A comprehensive review of ion beam application in modern materials research is provided, including the basics of ion beam physics and technology. The physics of ion-solid interactions for ion implantation, ion beam synthesis, sputtering and nano-patterning is treated in detail. Its applications in materials research, development and analysis, developments of special techniques and interaction mechanisms of ion beams with solid state matter result in the optimization of new material properties, which are discussed thoroughly. Solid-state properties optimization for functional materials such as doped semiconductors and metal layers for nano-electronics, metal alloys, and nano-patterned surfaces is demonstrated. The ion beam is an important tool for both materials processing and analysis. Researchers engaged in solid-state physics and materials research, engineers and technologists in the field of modern functional materials will welcome this text.
Ion implantation offers one of the best examples of a topic that starting from the basic research level has reached the high technology level within the framework of microelectronics. As the major or the unique procedure to selectively dope semiconductor materials for device fabrication, ion implantation takes advantage of the tremendous development of microelectronics and it evolves in a multidisciplinary frame. Physicists, chemists, materials sci entists, processing, device production, device design and ion beam engineers are all involved in this subject. The present monography deals with several aspects of ion implantation. The first chapter covers basic information on the physics of devices together with a brief description of the main trends in the field. The second chapter is devoted to ion im planters, including also high energy apparatus and a description of wafer charging and contaminants. Yield is a quite relevant is sue in the industrial surrounding and must be also discussed in the academic ambient. The slowing down of ions is treated in the third chapter both analytically and by numerical simulation meth ods. Channeling implants are described in some details in view of their relevance at the zero degree implants and of the available industrial parallel beam systems. Damage and its annealing are the key processes in ion implantation. Chapter four and five are dedicated to this extremely important subject.
Carbon has always been a unique and intriguing material from a funda mental standpoint and, at the same time, a material with many technological uses. Carbon-based materials, diamond, graphite and their many deriva tives, have attracted much attention in recent years for many reasons. Ion implantation, which has proven to be most useful in modifying the near surface properties of many kinds of materials, in particular semiconductors, has also been applied to carbon-based materials. This has yielded, mainly in the last decade, many scientifically interesting and technologically impor tant results. Reports on these studies have been published in a wide variety of journals and topical conferences, which often have little disciplinary overlap, and which often address very different audiences. The need for a review to cover in an integrated way the various diverse aspects of the field has become increasingly obvious. Such a review should allow the reader to get an overview of the research that has been done thus far, to gain an ap preciation of the common features in the response of the various carbon to ion impact, and to become aware of current research oppor allotropes tunities and unresolved questions waiting to be addressed. Realizing this, and having ourselves both contributed to the field, we decided to write a review paper summarizing the experimental and theoretical status of ion implantation into diamond, graphite and related materials.
Comprehensive guide to an important materials science technique for students and researchers.
Ion Implantation and Beam Processing covers the scientific and technological advances in the fields of ion implantation and beam processing. The book discusses the amorphization and crystallization of semiconductors; the application of the Boltzmann transport equation to ion implantation in semiconductors and multilayer targets; and the high energy density collision cascades and spike effects. The text also describes the implantation of insulators (ices and lithographic materials); the ion-bombardment-induced compositions changes in alloys and compounds; and the fundamentals and applications of ion beam and laser mixing. The high-dose implantation and the trends of ion implantation in silicon technology are also considered. The book further tackles the implantation in gaAs technology and the contacts and interconnections on semiconductors. Engineers and people involved in microelectronics will find the book invaluable.
Laser and Electron Beam Processing of Materials contains the papers presented at the symposium on "Laser and Electron Beam Processing of Materials," held in Cambridge, Massachusetts, in November 1979, sponsored by the Materials Research Society. The compilation presents reports and research papers on the use of directed energy sources, such as lasers and electron beams for materials processing. The majority of the materials presented emphasize results on semiconductor materials research. Substantial findings on research on metals, alloys, and other materials are presented as well. Topics covered by the papers include the use of scanned cw sources (both photons and electrons) to recrystallize amorphous layers, enhanced substitutional solubility, solute trapping, zone refining of impurities, and constitutional supercooling. The use of lasers and electron beams to anneal ion implant damage and contacts formation, processing of ion-implanted metals, and surface alloying of films deposited on metallic surfaces are also discussed. Metallurgists, engineers, and materials scientists will find the book very insightful.
The current status of the science and technology related to coatings, thin films and surface modifications produced by directed energy techniques is assessed in Materials Surface Processing by Directed Energy Techniques. The subject matter is divided into 20 chapters - each presented at a tutorial level – rich with fundamental science and experimental results. New trends and new results are also evoked to give an overview of future developments and applications. - Provides a broad overview on modern coating and thin film deposition techniques, and their applications - Presents and discusses various problems of physics and chemistry involved in the production, characterization and applications of coatings and thin films - Each chapter includes experimental results illustrating various models, mechanisms or theories
"New results in the field of ion implantation from the experienced scientists from different countries are presented in this book. Influence of ion implantation on structure and properties of semi-conducting materials, instrumental steels and alloys, nanocomposite coatings, including multielement ones, titanium alloys with the shape memory effect and super-elasticity are discussed in detail within this book. New data on novel applications of ion implantation for the modification and testing (radiation hardness simulation) of memristive devices, as well as application of ion implantation of group V dopants in the MCT epilayer are presented in this book. Potential use of ion implantation for the synthesis of Ag nanoparticles in a thin Si layer for the development of thin-film solar cells fabrication technology is discussed. The effect of ion implantation on the physical and mechanical properties of the hard alloy plates based on tungsten carbide and a cobalt binder is described. A study of the effects of ion implantation on the phase composition and the structure of materials is presented. The role of defects in the formation of the phase composition of the ion-implanted materials, structural-phase transformations in metals after ion implantation is investigated. This book will be interesting for professionals in the study of solid state physics, nuclear physics, physics of semi-conductors and nanomaterials. It can also be useful for masters and PhD students, as well as for professionals researching the fabrication and investigation of protective materials with enhanced physical-mechanical and tribological properties, good biocompatibility and resistance to irradiation"--