Investigation of SiC/Oxide Interface Structures by Spectroscopic Ellipsometry

We have investigated SiC/oxide interface structures by the use of spectroscopic ellipsometry. The depth profile of the optical constants of thermally grown oxide layers on SiC was obtained by observing the slope-shaped oxide layers, and the results suggest the existence of the interface layers, around 1 nm in thickness, having high refractive index than those of both SiC and SiO2. The wavelength dispersions of optical constants of the interface layers were measured in the range of visible to deep UV spectral region, and we found the interface layers have similar dispersion to that of SiC, though the refractive indices are around 1 larger than SiC, which suggests the interface layers are neither transition layers nor roughness layers, but modified SiC, e.g., strained and/or modified composition. By the use of an in-situ ellipsometer, real-time observation of SiC oxidation was performed, and the growth rate enhancement was found in the thin thickness regime as in the case of Si oxidation, which cannot be explained by the Deal-Grove model proposed for Si oxidation. From the measurements of the oxidation temperature and oxygen partial pressure dependences of oxidation rate in the initial stage of oxidation, we have discussed the interface structures and their formation mechanisms within the framework of the interfacial Si-C emission model we proposed for SiC oxidation mechanism

Unraveling the mechanisms responsible for the interfacial region formation in 4H-SiC dry thermal oxidation

Aiming to understand the processes involved in the formation of the transition region between SiO2 and SiC, known as the interfacial region, early steps of SiC oxidation were investigated using mainly nuclear reaction analyses. Oxidation kinetics reveals that an abrupt change in the oxidation mechanism is observed in C-face oxide films when their thickness is around 10 nm, while a continuous change in the oxidation mechanism is observed in Si-face oxide films with thicknesses up to about 4 nm. This last thickness corresponds to the maximum width of the interfacial region. Changes observed in the oxidation mechanism were related to oxidation reaction and interfacial atom emission that may take place during oxide film growth. Besides, the activation energies of such processes were obtained

Physics and Technology of Silicon Carbide Devices

Recently, some SiC power devices such as Schottky-barrier diodes (SBDs), metal-oxide-semiconductor field-effect-transistors (MOSFETs), junction FETs (JFETs), and their integrated modules have come onto the market. However, to stably supply them and reduce their cost, further improvements for material characterizations and those for device processing are still necessary. This book abundantly describes recent technologies on manufacturing, processing, characterization, modeling, and so on for SiC devices. In particular, for explanation of technologies, I was always careful to argue physics underlying the technologies as much as possible. If this book could be a little helpful to progress of SiC devices, it will be my unexpected happiness

Interaction of SiC thermal oxidation by-products with SiO2

We investigated oxygen incorporation and exchange during thermal growth of silicon oxide films on silicon carbide. This investigation was carried out in parallel with the thermal growth of silicon oxide films on silicon for comparison.We provide experimental evidence that oxidation by-products of silicon carbide out-diffuse and interact with the silicon oxide overlayer, incorporating C and O. This and other results are in sharp contrast to those obtained for silicon samples, constituting a key issue in the stability of any dielectric material used on silicon carbide

Characterisation of silicon carbide CMOS devices for high temperature applications

PhD ThesisIn recent years it has become increasingly apparent that there is a large demand for resilient electronics that can operate within environments that standard silicon electronics cease to function such as high power and high voltage applications, high temperatures, corrosive atmospheres and environments exposed to radiation. This has become even more essential due to increased demands for sustainable energy production and the reduction in carbon emissions worldwide, which has put a large burden on a wide range of industrial sectors who now have a significant demand for electronics to meet these needs including; military, space, aerospace, automotive, energy and nuclear. In extreme environments, where ambient temperatures may well exceed the physical limit of silicon-based technologies, SiC based technology offers a lower cost and a smaller footprint solution for operation in such environments due to its advantageous electrical properties such as a high breakdown electric field, high thermal conductivity and large saturation velocity. High quality material on large area wafers (150 mm) is now commercially available, allowing the fabrication of reliable high temperature, high frequency and high current power electronic devices, improving the already optimised silicon based structures. An important advantage of SiC is that it is the only wide band gap compound semiconductor that can be thermally oxidised to grow insulating, high quality SiO2 layers, which makes it an ideal candidate to replace silicon technologies for metal-oxide-semiconductor applications, which is the main focus of this research. Although the technology has made a number of major steps forward over recent years and the commercial manufacturing process has advanced significantly, there still remains a number of issues that need to be overcome in order to fully realise the potential of the material for electronic applications. This thesis describes the characterisation of 4H-SiC CMOS structures that were designed for high temperature applications and fabricated with varying gate dielectric treatments and process steps. The influence of process techniques on the characteristics of metal-oxide-semiconductor (MOS) devices has been investigated by means of electrical characterisation and the results have been compared to theoretical models. The C-V and I-V characteristics of both MOS capacitor and MOSFET structures with varying gate dielectrics on both n-type and p-type 4H-SiC have been analysed to explore the benefits of the varying process techniques that have been employed in the design of the devices. The results show that the field effect mobility characteristic of 4H-SiC MOSFETs are dominated at low perpendicular electric fields by Coulomb scattering and at high electric fields by low surface roughness mobility, which is due to the rough SiC-SiO2 interface. The findings also show that a thermally grown SiO2 layer at the semiconductor-dielectric interface is a beneficial process step that enhances the interfacial characteristics and increases the channel mobility of the MOSFETs. In addition to this it is also found that this technique provides the most beneficial characteristics on both n-type and p-type 4H-SiC, which suggests that it would be the most suitable treatment for a monolithic CMOS process. The impact of threshold voltage adjust ion implantation on both the MIS capacitor and MOSFET structures is also presented and shows that the increasing doses of nitrogen that are implanted to adjust the threshold voltage act to improve the device performance by acting to modify the charge at the interface or within the gate oxide and therefore increase the field effect mobility of the studied devices.Engineering and Physical Sciences Research Council (EPSRC) and Raytheon U

High-responsivity SiC Ultraviolet Photodetectors with SiO2 and Al2O3 Films

Silicon carbide (SiC) has shown considerable potential for ultraviolet (UV) photodetectors due to its properties such as wide band gap (3.26 eV for 4H-SiC), high break down electric field and high thermal stability. 4H-SiC-based UV photodetectors such as Schottky, metal-semiconductor-metal (MSM), metal-insulator-semiconductor (MIS) and avalanche have been presenting excellent performance for UV detection application in flame detection, ozone-hole sensing, short-range communication, etc. Generally, the most widely used antireflection coating and passivation layer for 4H-SiC-based photodetectors are native SiO2 grown by heating 4H-SiC in O2 in order to improve the absorption and passivation of photodetectors. Nevertheless, the thermally grown SiO2 single layer suffers from high reflection, large absorption and inaccurate thickness. Therefore, in this chapter, UV antireflection coatings were designed, fabricated and applied in order to reduce optical losses and improve the quantum efficiency (QE) of 4H-SiC-based photodetectors. The important results will be introduced as follows

Feature Papers in Electronic Materials Section

This book entitled "Feature Papers in Electronic Materials Section" is a collection of selected papers recently published on the journal Materials, focusing on the latest advances in electronic materials and devices in different fields (e.g., power- and high-frequency electronics, optoelectronic devices, detectors, etc.). In the first part of the book, many articles are dedicated to wide band gap semiconductors (e.g., SiC, GaN, Ga2O3, diamond), focusing on the current relevant materials and devices technology issues. The second part of the book is a miscellaneous of other electronics materials for various applications, including two-dimensional materials for optoelectronic and high-frequency devices. Finally, some recent advances in materials and flexible sensors for bioelectronics and medical applications are presented at the end of the book

CVD-Wachstum von (001) und (111) 3C-SiC Epi-Schichten und ihre Grenzflächenreaktivität mit dielektrischen Praseodymiumoxidschichten

In this work, growth and characterisation of 3C-SiC thin films, investigation of oxidation of thus prepared layers and Pr-silicate and AlON based interface with SiC have been studied. Chemical vapor deposition of 3C-SiC thin films on Si(001) and Si(111) substrates has been investigated. Prior to the actual SiC growth, preparation of initial buffer layers of SiC was done. Using such a buffer layer, epitaxial growth of 3C-SiC has been achieved on Si(111) and Si(001) substrates. The temperature of 1100°C and 1150°C has been determined to be the optimal temperature for 3C-SiC growth on Si (111) and Si(001) substrates respectively. The oxidation studies on SiC revealed that a slow oxidation process at moderate temperatures in steps was useful in reducing and suppressing the g-C at the SiO2/SiC interface. Clean, graphitefree SiO2 has been successfully grown on 3C-SiC by silicon evaporation and UHV anneal. For the application of high-k Pr2O3 on silicon carbide, plausible interlayer, Pr-Silicate and AlON, have been investigated. Praseodymium silicate has been prepared successfully completely consuming the SiO2 and simultaneously suppressing the graphitic carbon formation. A comparatively more stable interlayer using AlON has been achieved. This interlayer mainly consists of stable phases of AlN along with some amount of Pr-aluminates and CN. Such layers act as a reaction barrier between Pr2O3 and SiC, and simultaneously provide higher band offsets.Im Rahmen dieser Arbeit wird das Wachstum und die Charakterisierung von 3C-SiC Filmen, deren Oxidation, sowie das darauf präparierte Pr-Silikat und die AlON abgeleitete Grenzfläche untersucht. Dünne 3C-SiC Filme wurden auf Si(001) und Si(111) Oberflächen mit Hilfe von Chemical Vapor Deposition Verfahren hergestellt. Vor dem eigentlichen SiC-Wachstum wurde eine SiC Zwischenschicht präpariert. Durch diese Buffer-Schicht wurde das epitaktische Wachstum von 3C-SiC auf Si(111) und Si(001) erst ermöglicht. Als optimale Präparationstemperaturen für 3C-SiC auf Si(111) und Si(001) konnten 1100°C und 1150°C gefunden werden. Im Verlaufe der Oxidation hat sich ein langsamer Stufenprozess mit moderaten Temperaturen als hilfreich erwiesen, um die Graphitisierung an der SiO2/SiC Grenzfläche zu minimieren. Sauberes, graphitfreies SiO2 konnte somit auf 3C-SiC mit Hilfe von Si-Evaporation und Heizen im Vakuum hergestellt werden. Für mögliche Anwendung von Pr2O3 auf Siliziumkarbid als high-k Dielektrikum wurden weiterhin Pr-Silikate und AlON untersucht. Praseodymium-Silikat konnte erfolgreich auf der SiO2 Oberfläche abgeschieden werden und gleichzeitig die Graphitisierung verhindert werden. Im Vergleich hierzu konnten sehr stabile Grenzflächen mit AlON hergestellt werden. Diese Grenzflächen bestehen hauptsächlich aus AlN mit Anteilen von Pr-Al Komplexen. Diese Schichten können als Reaktionsbarrieren zwischen Pr2O3 und SiC dienen und gleichzeitig den Band-Offset vergrößern

Size Dependence of Nanoscale Wear of Silicon Carbide

Nanoscale, single-asperity wear of single-crystal silicon carbide (sc-SiC) and nanocrystalline silicon carbide (nc-SiC) is investigated using single-crystal diamond nanoindenter tips and nanocrystalline diamond atomic force microscopy (AFM) tips under dry conditions, and the wear behavior is compared to that of single-crystal silicon with both thin and thick native oxide layers. We discovered a transition in the relative wear resistance of the SiC samples compared to that of Si as a function of contact size. With larger nanoindenter tips (tip radius around 370 nm), the wear resistances of both sc-SiC and nc-SiC are higher than that of Si. This result is expected from the Archard's equation because SiC is harder than Si. However, with the smaller AFM tips (tip radius around 20 nm), the wear resistances of sc-SiC and nc-SiC are lower than that of Si, despite the fact that the contact pressures are comparable to those applied with the nanoindenter tips, and the plastic zones are well-developed in both sets of wear experiments. We attribute the decrease in the relative wear resistance of SiC compared to that of Si to a transition from a wear regime dominated by the materials' resistance to plastic deformation (i.e., hardness) to a regime dominated by the materials' resistance to interfacial shear. This conclusion is supported by our AFM studies of wearless friction, which reveal that the interfacial shear strength of SiC is higher than that of Si. The contributions of surface roughness and surface chemistry to differences in interfacial shear strength are also discussed