Effects of Nuclear Radiation on Silicon Carbide Diodes
Author: Lester E. Schott
Publisher:
Published: 1967
Total Pages: 28
ISBN-13:
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Author: Lester E. Schott
Publisher:
Published: 1967
Total Pages: 28
ISBN-13:
DOWNLOAD EBOOKAuthor: A.A. Lebedev
Publisher: Materials Research Forum LLC
Published: 2017
Total Pages: 172
ISBN-13: 1945291117
DOWNLOAD EBOOKThe book reviews the most interesting research concerning the radiation defects formed in 6H-, 4H-, and 3C-SiC under irradiation with electrons, neutrons, and some kinds of ions. The electrical parameters that make SiC a promising material for applications in modern electronics are discussed in detail. Specific features of the crystal structure of SiC are considered. It is shown that, when wide-bandgap semiconductors are studied, it is necessary to take into account the temperature dependence of the carrier removal rate, which is a standard parameter for determining the radiation hardness of semiconductors. The carrier removal rate values obtained by irradiation of various SiC polytypes with n- and p-type conductivity are analyzed in relation to the type and energy of the irradiating particles. The influence exerted by the energy of charged particles on how radiation defects are formed and conductivity is compensated in semiconductors under irradiation is analyzed. Furthermore, the possibility to produce controlled transformation of silicon carbide polytype is considered. The involvement of radiation defects in radiative and nonradiative recombination processes in SiC is analyzed. Data are also presented regarding the degradation of particular SiC electronic devices under the influence of radiation and a conclusion is made regarding the radiation resistance of SiC. Lastly, the radiation hardness of devices based on silicon and silicon carbide are compared.
Author: James M. Kenney
Publisher:
Published: 1976
Total Pages: 36
ISBN-13:
DOWNLOAD EBOOKAuthor: James M. Kenney
Publisher:
Published: 1976
Total Pages: 36
ISBN-13:
DOWNLOAD EBOOKAuthor: Jonathan Andrew Kulisek
Publisher:
Published: 2006
Total Pages: 182
ISBN-13:
DOWNLOAD EBOOKAbstract: The objective of this work is to support NASA's space mission efforts by analyzing and predicting the effects of neutron radiation damage on power semiconductor devices made of Si and SiC, which can be used in power circuits aboard NASA's spacecraft. This research focuses primarily on diodes for their widespread use in power electronic circuits and as neutron detectors for nuclear reactor-powered spacecraft. Schottky diodes were investigated, in particular, due to their known, inherent resistance to radiation damage and thus possible use in environments with high levels of radiation. Several computer codes were used in conjunction with measured, experimental data obtained with the use of the Ohio State University Research Reactor (OSURR) to study the effects of neutron radiation on the electrical performance parameters of Schottky diodes. The Si and SiC power Schottky diodes that were irradiated in the OSURR were exposed to high levels of neutron radiation, yet the electrical performance parameters associated with their metal-semiconductor junctions remained unaffected, and they exhibited relatively systematic, yet modest degradation with respect to electrical performance parameters associated with semiconductor bulk damage, such as series resistance, R. As for the reverse I-V characteristics, the SiC Schottky diodes exhibited a decrease in leakage current and an increase in breakdown voltage with increasing neutron fluence. For the Si Schottky diodes, the leakage current increased and the breakdown voltage decreased with increasing neutron fluence, but only to a relatively slight degree. From these results, it appears that the Si and SiC power Schottky diodes investigated in this study can tolerate high levels of radiation damage without suffering a severe degradation in electrical performance, and thus show promise for use in space radiation environments.
Author: F. J. Reid
Publisher:
Published: 1960
Total Pages: 50
ISBN-13:
DOWNLOAD EBOOKData are presented on investigations of standard silicon and germanium transistors, diodes, rectifiers, and such devices as unipolar transistors, Esaki diodes, and SiC, GaP, and selenium rectifiers. The data are intended to be sufficiently inclusive to make it valuable as a guide on effects which can be anticipated from nuclear radiation on electronic components utilizing semiconductor devices. (Author).
Author: Hailong Chen
Publisher:
Published: 2020
Total Pages: 161
ISBN-13:
DOWNLOAD EBOOKRadiation is of great importance in both fundamental science (e.g., understanding black holes, exploring the time evolution and the origin of the universe) and technological applications (e.g., diagnosing and treating diseases in medicine, and producing electricity at nuclear plant). Among all the radiation studies, radiation in semiconductor materials attracts the most attention in the information era with numerous semiconductor devices operating in space and on earth. Although silicon (Si) still dominates the semiconductor industry, a number of wide bandgap (WBG) semiconductors have demonstrated advantages in harsh environment applications. Among them, silicon carbide (SiC), with a family of polytypes and excellent properties such as wide bandgap (2.3-3.2 eV), high displacement energies (20-35 eV), excellent elastic modulus (~200-700 GPa) and outstanding thermal conductivity (~500 W m-1K-1), has shown great potential for high temperature, high power, and radiation resistant applications. A quite large body of work has been performed during recent decades to understand the radiation effects in the SiC electronic devices, such as field effect transistors (FETs), bipolar junction transistors (BJTs), and diodes. Meantime, while micro/nanoelectromechanical systems (M/NEMS) have gained tremendous advancements and made great impact on many important applications including inertial sensing (e.g., gyroscopes, accelerators), radio-frequency (RF) signal processing and communication, radiation study in M/NEMS has been quite limited, especially for those based on beyond-Si materials. This dissertation makes an initial thrust toward investigating radiation effects in SiC M/NEMS. First, we develop an innovative 3D integrated MEMS platform, by exploiting a scheme consisting of an array of vertically stacked SiC thin diaphragms (and Si ones for comparison). This integrated design and configuration not only scientifically enables probing different radiation effects (with clear reference and control samples) in a 3D fashion, but also economically evades very expensive, repetitive tests on individual devices. Further, we demonstrate cantilever-shaped 3C-SiC multimode MEMS resonators for real-time detection of ultraviolet (UV) radiation. In parallel, we have also developed Si counterparts of the SiC devices to help elucidate how SiC behaves differently from Si for radiation sensing and detecting. Finally, we explore the displacement and ionizing irradiation effects in SiC NEMS switching devices to gain comprehensive and in-depth understanding of the science behind the radiation effects in nanoscale structures made of thin SiC on SiO2. The investigation of NEMS switches before, during, and after proton and X-ray irradiation reveals how energetic particles cause threshold voltage modification, due to the dislocation damage in SiC crystal and how ionizing effects may affect the performance of these nanoscale devices.
Author: Julian F. Been
Publisher:
Published: 1968
Total Pages: 26
ISBN-13:
DOWNLOAD EBOOKAuthor: Los Alamos Scientific Laboratory
Publisher:
Published: 1961
Total Pages: 80
ISBN-13:
DOWNLOAD EBOOKAuthor: Julian F. Been
Publisher:
Published: 1970
Total Pages: 36
ISBN-13:
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