Atomic layer deposition, formerly called atomic layer epitaxy, was developed in the 1970s to meet the needs of producing high-quality, large-area fl at displays with perfect structure and process controllability. Nowadays, creating nanomaterials and producing nanostructures with structural perfection is an important goal for many applications in nanotechnology. As ALD is one of the important techniques which offers good control over the surface structures created, it is more and more in the focus of scientists. The book is structured in such a way to fi t both the need of the expert reader (due to the systematic presentation of the results at the forefront of the technique and their applications) and the ones of students and newcomers to the fi eld (through the first part detailing the basic aspects of the technique). This book is a must-have for all Materials Scientists, Surface Chemists, Physicists, and Scientists in the Semiconductor Industry.

This book provides a detailed study of the Atomic Layer Epitaxy technique (ALE), its development, current and potential applications. The rapid development of coating technologies over the last 25 years has been instrumental in generating interest and expertise in thin films of materials, and indeed the market for thin film coatings is currently £3 billion with projected annual growth of 20 to 30% [1]. ALE is typical of thin-film processes in that problems in the processing or preparation of good quality epitaxial films have been overcome, resulting in better performance, novel applications of previously unsuitable materials, and the development of new devices. Many materials exhibit interesting and novel properties when prepared as thin films and doped. Vapour-deposited coatings and films are used extensively in the semiconductor and related industries for making single devices, integrated circuits, microwave hybrid integrated circuits, compact discs, solar reflective glazing, fibre optics, photo voltaic cells, sensors, displays, and many other products in general, everyday use. The ALE technique was developed by a research team led by Tuomo Suntola, working for Instrumentarium Oy in Finland. The key members of this team were lorma Antson, Arto Pakkala and Sven Lindfors. In 1977, the research team moved from Instrumentarium to Lohja Corporation, where they continued the development of ALE and were granted a patent in the same year. By 1980, the technique was sufficiently advanced that they were producing flat-screen electroluminescent displays based on a manganese-doped zinc sulphide layer.

Since the first edition was published in 2008, Atomic Layer Deposition (ALD) has emerged as a powerful, and sometimes preferred, deposition technology. The new edition of this groundbreaking monograph is the first text to review the subject of ALD comprehensively from a practical perspective. It covers ALD's application to microelectronics (MEMS) and nanotechnology; many important new and emerging applications; thermal processes for ALD growth of nanometer thick films of semiconductors, oxides, metals and nitrides; and the formation of organic and hybrid materials.

Volume IIIA Basic TechniquesHandbook of Crystal Growth, Second Edition Volume IIIA (Basic Techniques), edited by chemical and biological engineering expert Thomas F. Kuech, presents the underpinning science and technology associated with epitaxial growth as well as highlighting many of the chief and burgeoning areas for epitaxial growth. Volume IIIA focuses on major growth techniques which are used both in the scientific investigation of crystal growth processes and commercial development of advanced epitaxial structures. Techniques based on vacuum deposition, vapor phase epitaxy, and liquid and solid phase epitaxy are presented along with new techniques for the development of three-dimensional nano-and micro-structures.Volume IIIB Materials, Processes, and TechnologyHandbook of Crystal Growth, Second Edition Volume IIIB (Materials, Processes, and Technology), edited by chemical and biological engineering expert Thomas F. Kuech, describes both specific techniques for epitaxial growth as well as an array of materials-specific growth processes. The volume begins by presenting variations on epitaxial growth process where the kinetic processes are used to develop new types of materials at low temperatures. Optical and physical characterizations of epitaxial films are discussed for both in situ and exit to characterization of epitaxial materials. The remainder of the volume presents both the epitaxial growth processes associated with key technology materials as well as unique structures such as monolayer and two dimensional materials.Volume IIIA Basic Techniques - Provides an introduction to the chief epitaxial growth processes and the underpinning scientific concepts used to understand and develop new processes. - Presents new techniques and technologies for the development of three-dimensional structures such as quantum dots, nano-wires, rods and patterned growth - Introduces and utilizes basic concepts of thermodynamics, transport, and a wide cross-section of kinetic processes which form the atomic level text of growth process Volume IIIB Materials, Processes, and Technology - Describes atomic level epitaxial deposition and other low temperature growth techniques - Presents both the development of thermal and lattice mismatched streams as the techniques used to characterize the structural properties of these materials - Presents in-depth discussion of the epitaxial growth techniques associated with silicone silicone-based materials, compound semiconductors, semiconducting nitrides, and refractory materials

Offering thorough coverage of atomic layer deposition (ALD), this book moves from basic chemistry of ALD and modeling of processes to examine ALD in memory, logic devices and machines. Reviews history, operating principles and ALD processes for each device.

This book provides a detailed study of the Atomic Layer Epitaxy technique (ALE), its development, current and potential applications. The rapid development of coating technologies over the last 25 years has been instrumental in generating interest and expertise in thin films of materials, and indeed the market for thin film coatings is currently £3 billion with projected annual growth of 20 to 30% [1]. ALE is typical of thin-film processes in that problems in the processing or preparation of good quality epitaxial films have been overcome, resulting in better performance, novel applications of previously unsuitable materials, and the development of new devices. Many materials exhibit interesting and novel properties when prepared as thin films and doped. Vapour-deposited coatings and films are used extensively in the semiconductor and related industries for making single devices, integrated circuits, microwave hybrid integrated circuits, compact discs, solar reflective glazing, fibre optics, photo voltaic cells, sensors, displays, and many other products in general, everyday use. The ALE technique was developed by a research team led by Tuomo Suntola, working for Instrumentarium Oy in Finland. The key members of this team were lorma Antson, Arto Pakkala and Sven Lindfors. In 1977, the research team moved from Instrumentarium to Lohja Corporation, where they continued the development of ALE and were granted a patent in the same year. By 1980, the technique was sufficiently advanced that they were producing flat-screen electroluminescent displays based on a manganese-doped zinc sulphide layer.

"The book is one of the most comprehensive overviews ever written on the key aspects of chemical vapour deposition processes and it is more comprehensive, technically detailed and up-to-date than other books on CVD. The contributing authors are all practising CVD technologists and are leading international experts in the field of CVD. It presents a logical and progressive overview of the various aspects of CVD processes. Basic concepts, such as the various types of CVD processes, the design of CVD reactors, reaction modelling and CVD precursor chemistry are covered in the first few"--Jacket

The Springer Reference Work Handbook of Manufacturing Engineering and Technology provides overviews and in-depth and authoritative analyses on the basic and cutting-edge manufacturing technologies and sciences across a broad spectrum of areas. These topics are commonly encountered in industries as well as in academia. Manufacturing engineering curricula across universities are now essential topics covered in major universities worldwide.

The characterization of epitaxial layers and their surfaces has benefitted a lot from the enormous progress of optical analysis techniques during the last decade. In particular, the dramatic improvement of the structural quality of semiconductor epilayers and heterostructures results to a great deal from the level of sophistication achieved with such analysis techniques. First of all, optical techniques are nondestructive and their sensitivity has been improved to such an extent that nowadays the epilayer analysis can be performed on layers with thicknesses on the atomic scale. Furthermore, the spatial and temporal resolution have been pushed to such limits that real time observation of surface processes during epitaxial growth is possible with techniques like reflectance difference spectroscopy. Of course, optical spectroscopies complement techniques based on the inter action of electrons with matter, but whereas the latter usually require high or ultrahigh vacuum conditions, the former ones can be applied in different environments as well. This advantage could turn out extremely important for a rather technological point of view, i.e. for the surveillance of modern semiconductor processes. Despite the large potential of techniques based on the interaction of electromagnetic waves with surfaces and epilayers, optical techniques are apparently moving only slowly into this area of technology. One reason for this might be that some prejudices still exist regarding their sensitivity.

Molecular Beam Epitaxy (MBE): From Research to Mass Production, Second Edition, provides a comprehensive overview of the latest MBE research and applications in epitaxial growth, along with a detailed discussion and 'how to' on processing molecular or atomic beams that occur on the surface of a heated crystalline substrate in a vacuum. The techniques addressed in the book can be deployed wherever precise thin-film devices with enhanced and unique properties for computing, optics or photonics are required. It includes new semiconductor materials, new device structures that are commercially available, and many that are at the advanced research stage. This second edition covers the advances made by MBE, both in research and in the mass production of electronic and optoelectronic devices. Enhancements include new chapters on MBE growth of 2D materials, Si-Ge materials, AIN and GaN materials, and hybrid ferromagnet and semiconductor structures. - Condenses the fundamental science of MBE into a modern reference, speeding up literature review - Discusses new materials, novel applications and new device structures, grounding current commercial applications with modern understanding in industry and research - Includes coverage of MBE as mass production epitaxial technology and how it enhances processing efficiency and throughput for the semiconductor industry and nanostructured semiconductor materials research community