Download Free Epitaxial Growth Of Semimetallic Hybrid Substrate Systems For Low Temperature Optoelectronic Integration Of Nitrides On Silicon Book in PDF and EPUB Free Download. You can read online Epitaxial Growth Of Semimetallic Hybrid Substrate Systems For Low Temperature Optoelectronic Integration Of Nitrides On Silicon and write the review.

Microelectronics industry has experienced a tremendous change over the last few decades and has shown that Moore's law has been followed by doubling the number of transistors on the chip every 18 months. However, continuous scaling down of the transistors size is reaching the physical limits and data transfer through metal interconnects will not be able to catch up with the increasing data processing speed in the future. Therefore, optical data transfer between chips and on-chip has been widely investigated. Silicon based optoelectronics has received phenomenal attention since Si has been the core material on which microelectronic industry has been built. However, due to the indirect bandgap nature of Si, its optical characteristics fall short compared to similar III-IV semiconductors. The efforts in III-V incorporation on Si substrate have not been successful due to the incompatibility of the growth with complementary metal oxide semiconductor processing. Germanium has been studied in order to develop a Si compatible technology and it has been shown that a direct bandgap material is achievable by alloying Sn in Ge. Further investigations on Si-Ge-Sn material system showed its viability as a technology that can be used for fabrication of Si-compatible light source and detectors. The work presented in this dissertation is focused on the low temperature growth of Si-Ge-Sn alloys. High quality crystalline homoepitaxial silicon films were deposited at 250 °C using a plasma-enhanced chemical vapor deposition (PECVD) system. Strain-relaxed Ge and SiGe films were also grown on Si substrate at 350-550 °C in a reduced pressure CVD system. Commercial precursors of silane and germane were used to grow the films at different chamber pressures. Germanium-tin and silicon-germanium-tin alloys were grown by a cold-wall chemical vapor deposition system at low temperatures (300-450 °C) directly on Si substrates. Two different delivery systems were adopted for the delivery of stannic chloride and deuterated stannane as Sn precursors along with silane and germane. Crystallinity and growth quality of the films were investigated through material characterization methods including X-ray diffraction, scanning electron microscopy and transmission electron microscopy. Elemental characterization of the films was done using Rutherford backscattering measurement and energy-dispersive X-ray spectroscopy. Moreover, optical characterizations were performed using Raman spectroscopy and photoluminescence on the samples to investigate Sn incorporation in the films. Additionally, compressively strained (
Low temperature processes for semiconductors have been recently under intensive development to fabricate controlled device structures with minute dimensions in order to achieve the highest device performance and new device functions as well as high integration density. Comprising reviews by experts long involved in the respective pioneering work, this volume makes a useful contribution toward maturing the process of low temperature epitaxy as a whole.
Epitaxial Silicon Technology is a single-volume, in-depth review of all the silicon epitaxial growth techniques. This technology is being extended to the growth of epitaxial layers on insulating substrates by means of a variety of lateral seeding approaches. This book is divided into five chapters, and the opening chapter describes the growth of silicon layers by vapor-phase epitaxy, considering both atmospheric and low-pressure growth. The second chapter discusses molecular-beam epitaxial growth of silicon, providing a unique ability to grow very thin layers with precisely controlled doping characteristics. The third chapter introduces the silicon liquid-phase epitaxy, in which the growth of silicon layers arose from a need to decrease the growth temperature and to suppress autodoping. The fourth chapter addresses the growth of silicon on sapphire for improving the radiation hardness of CMOS integrated circuits. The fifth chapter deals with the advances in the application of silicon epitaxial growth. This chapter also discusses the formation of epitaxial layers of silicon on insulators, such as silicon dioxide, which do not provide a natural single crystal surface for growth. Each chapter begins with a discussion on the fundamental transport mechanisms and the kinetics governing the growth rate, followed by a description of the electrical properties that can be achieved in the layers and the restrictions imposed by the growth technique upon the control over its electrical characteristics. Each chapter concludes with a discussion on the applications of the particular growth technique. This reference material will be useful for process technologists and engineers who may need to apply epitaxial growth for device fabrication.
Newly developed semiconductor microstructures can now guide light and electrons resulting in important consequences for state-of-the-art electronic and photonic devices. This volume introduces a new generation of epitaxial microstructures. Special emphasis has been given to atomic control during growth and the interrelationship between the atomic arrangements and the properties of the structures. Atomic-level control of semiconductor microstructures Molecular beam epitaxy, metal-organic chemical vapor deposition Quantum wells and quantum wires Lasers, photon(IR)detectors, heterostructure transistors
What seems routine today was not always so. The field of Si-based heterostructures rests solidly on the shoulders of materials scientists and crystal growers, those purveyors of the semiconductor “black arts” associated with the deposition of pristine films of nanoscale dimensionality onto enormous Si wafers with near infinite precision. We can now grow near-defect free, nanoscale films of Si and SiGe strained-layer epitaxy compatible with conventional high-volume silicon integrated circuit manufacturing. SiGe and Si Strained-Layer Epitaxy for Silicon Heterostructure Devices tells the materials side of the story and details the many advances in the Si-SiGe strained-layer epitaxy for device applications. Drawn from the comprehensive and well-reviewed Silicon Heterostructure Handbook, this volume defines and details the many advances in the Si/SiGe strained-layer epitaxy for device applications. Mining the talents of an international panel of experts, the book covers modern SiGe epitaxial growth techniques, epi defects and dopant diffusion in thin films, stability constraints, and electronic properties of SiGe, strained Si, and Si-C alloys. It includes appendices on topics such as the properties of Si and Ge, the generalized Moll-Ross relations, integral charge-control relations, and sample SiGe HBT compact model parameters.
Epitaxial Growth of Complex Metal Oxides, Second Edition reviews techniques and recent developments in the fabrication quality of complex metal oxides, which are facilitating advances in electronic, magnetic and optical applications. Sections review the key techniques involved in the epitaxial growth of complex metal oxides and explore the effects of strain and stoichiometry on crystal structure and related properties in thin film oxides. Finally, the book concludes by discussing selected examples of important applications of complex metal oxide thin films, including optoelectronics, batteries, spintronics and neuromorphic applications. This new edition has been fully updated, with brand new chapters on topics such as atomic layer deposition, interfaces, STEM-EELs, and the epitaxial growth of multiferroics, ferroelectrics and nanocomposites. Examines the techniques used in epitaxial thin film growth for complex oxides, including atomic layer deposition, sputtering techniques, molecular beam epitaxy, and chemical solution deposition techniques Reviews materials design strategies and materials property analysis methods, including the impacts of defects, strain, interfaces and stoichiometry Describes key applications of epitaxially grown metal oxides, including optoelectronics, batteries, spintronics and neuromorphic applications
Proceedings of the 1st International Conference on Epitaxial Crystal Growth, Budapest, Hungary, April 1990