High Temperature Testingand Noise Integration of a Buck Converter usingSilicon and Silicon Carbide Diodes.

This project includes comparison of the advantages of enhanced SiC device performance at elevated temperatures over Si devices in a buck type DC/DC converter circuit. Being that elevated temperatures in a circuit have always caused energy losses and deviation in results, the manufacturers of silicon technology came up with a much more sophisticated Silicon Carbide technology which dramatically reduces the above mentioned two factors. The scope is mainly to examine thermal effects at high temperatures on the performance characteristics of the buck converter circuit, diode losses, switching losses and overall system losses. This project also includes effect of noise integrated buck converter circuit. So, comparison is being made between that of noise integrated and noiseless circuit both of which are being varied from a low temperature up to temperature of 300 Celsius. This project mainly utilizes PSPICE software to achieve the above stated results. Reasons and causes as to the increase of losses as the increase of temperature have been discussed in this project. Also the source of noise and practical ways of reducing noises in buck converter circuits is being stated in this project. Withpropertabulation and graphs of results this project enables to deeply understand Silicon Carbide technology used in buck converter circuit, which is a subject to elevated temperatures and noise

Particle-Based Modeling of Reliability for Millimeter-Wave GaN Devices for Power Amplifier Applications

abstract: In this work, an advanced simulation study of reliability in millimeter-wave (mm-wave) GaN Devices for power amplifier (PA) applications is performed by means of a particle-based full band Cellular Monte Carlo device simulator (CMC). The goal of the study is to obtain a systematic characterization of the performance of GaN devices operating in DC, small signal AC and large-signal radio-frequency (RF) conditions emphasizing on the microscopic properties that correlate to degradation of device performance such as generation of hot carriers, presence of material defects and self-heating effects. First, a review of concepts concerning GaN technology, devices, reliability mechanisms and PA design is presented in chapter 2. Then, in chapter 3 a study of non-idealities of AlGaN/GaN heterojunction diodes is performed, demonstrating that mole fraction variations and the presence of unintentional Schottky contacts are the main limiting factor for high current drive of the devices under study. Chapter 4 consists in a study of hot electron generation in GaN HEMTs, in terms of the accurate simulation of the electron energy distribution function (EDF) obtained under DC and RF operation, taking into account frequency and temperature variations. The calculated EDFs suggest that Class AB PAs operating at low frequency (10 GHz) are more robust to hot carrier effects than when operating under DC or high frequency RF (up to 40 GHz). Also, operation under Class A yields higher EDFs than Class AB indicating lower reliability. This study is followed in chapter 5 by the proposal of a novel π-Shaped gate contact for GaN HEMTs which effectively reduces the hot electron generation while preserving device performance. Finally, in chapter 6 the electro-thermal characterization of GaN-on-Si HEMTs is performed by means of an expanded CMC framework, where charge and heat transport are self-consistently coupled. After the electro-thermal model is validated to experimental data, the assessment of self-heating under lateral scaling is considered.Dissertation/ThesisDoctoral Dissertation Electrical Engineering 201

Thermal and electrical stability assessment of AlGaN/GaN Metal-Oxide-Semiconductor High Electron Mobility Transistors (MOS-HEMT) with HfO2 gate dielectric.

AlGaN/GaN HEMTs and MOS-HEMTs using HfO2 as gate dielectric have been analyzed at room temperature, after STA and TC test, during off-state electrical step stress, HTRB and PBTI tests. Results showed that the leakage current in as-fabricated MOS-HEMTs decreased by 106 and the on/off ratio increased by over 104 than the HEMTs. Moreover, it was even higher after a STA test, up to 108, in the MOS-HEMTs, and the surface trapping effects were mitigated, especially if a KOH cleaning was used before HfO2 deposition. The MOS-HEMTs also showed higher electrical stability after off-state step electrical stress, HTRB and PBTI tests.pre-print732 K

The 2018 GaN Power Electronics Roadmap

Gallium nitride (GaN) is a compound semiconductor that has tremendous potential to facilitate economic growth in a semiconductor industry that is silicon-based and currently faced with diminishing returns of performance versus cost of investment. At a material level, its high electric field strength and electron mobility have already shown tremendous potential for high frequency communications and photonic applications. Advances in growth on commercially viable large area substrates are now at the point where power conversion applications of GaN are at the cusp of commercialisation. The future for building on the work described here in ways driven by specific challenges emerging from entirely new markets and applications is very exciting. This collection of GaN technology developments is therefore not itself a road map but a valuable collection of global state-of-the-art GaN research that will inform the next phase of the technology as market driven requirements evolve. First generation production devices are igniting large new markets and applications that can only be achieved using the advantages of higher speed, low specific resistivity and low saturation switching transistors. Major investments are being made by industrial companies in a wide variety of markets exploring the use of the technology in new circuit topologies, packaging solutions and system architectures that are required to achieve and optimise the system advantages offered by GaN transistors. It is this momentum that will drive priorities for the next stages of device research gathered here

Characterization and Modeling of Semiconductor Power Devices Reliability

This thesis aims at studying, characterizing and modeling the trapping and de-trapping mechanisms occurring during the ON-state operation mode and leading to the degradation of semiconductor power devices. In this operating condition, the combined effect of moderate electric fields, high currents and temperatures due to self-heating effects can seriously affect the long-term reliability leading to device failure. Detailed analyses are performed on both silicon and gallium nitride based technologies by means of accelerated life test methods and electro-thermal simulations, aimed at understanding the physical origins of the degradation. In particular, this thesis provides the following contributions: i) the role of the interface and oxide trapped charge induced by negative bias temperature instability (NBTI) stress in p-channel Si-based U-MOSFETs is investigated. The impact of relevant electrical and physical parameters, such as stress voltage, recovery voltage and temperature, is accounted for and proper models are also proposed. In the field of innovative semiconductor power devices, this work focuses on the study of GaN-based devices. In particular, three different subtopics are considered: ii) a thermal model, accounting for the temperature dependence of the thermal boundary resistance (TBR), is implemented in TCAD simulator in order to realistically model self-heating effects in GaN-based power devices; iii) the degradation mechanisms induced by ON-state stress in GaN-based Schottky barrier diodes (SBDs) are proposed by analyzing their dependence on the device geometry; iv) the trapping mechanisms underlying the time-dependent gate breakdown and their effects on the performance of GaN-based power HEMTs with p-type gate are investigated, and an original empirical model representing the relationship between gate leakage current and time to failure is proposed

Wide-bandgap Semiconductors in Space: Appreciating the Benefits but Understanding the Risks

Dr. Jean-Marie Lauenstein, NASA Goddard Space Flight Center, will present the radiation challenges of adopting wide-bandgap semiconductors for space applications. Wide-bandgap devices are attractive for space applications due to improved performance such as faster switching speeds, lower power losses, and their ability to operate at higher temperature as compared with their silicon counterparts. Their tolerance to total ionizing dose levels (> 100 krad(Si)) further enhances the desirability of these technologies. This short course will focus on silicon carbide and gallium nitride power rectifying, switching, and RF devices as these technologies are now readily available commercially. The radiation hardness assurance issues presented by the heavy-ion radiation environment will be discussed

GaN-based power devices: Physics, reliability, and perspectives

Over the last decade, gallium nitride (GaN) has emerged as an excellent material for the fabrication of power devices. Among the semicon- ductors for which power devices are already available in the market, GaN has the widest energy gap, the largest critical field, and the highest saturation velocity, thus representing an excellent material for the fabrication of high-speed/high-voltage components. The presence of spon- taneous and piezoelectric polarization allows us to create a two-dimensional electron gas, with high mobility and large channel density, in the absence of any doping, thanks to the use of AlGaN/GaN heterostructures. This contributes to minimize resistive losses; at the same time, for GaN transistors, switching losses are very low, thanks to the small parasitic capacitances and switching charges. Device scaling and monolithic integration enable a high-frequency operation, with consequent advantages in terms of miniaturization. For high power/high- voltage operation, vertical device architectures are being proposed and investigated, and three-dimensional structures—fin-shaped, trench- structured, nanowire-based—are demonstrating great potential. Contrary to Si, GaN is a relatively young material: trapping and degradation processes must be understood and described in detail, with the aim of optimizing device stability and reliability. This Tutorial describes the physics, technology, and reliability of GaN-based power devices: in the first part of the article, starting from a discussion of the main proper- ties of the material, the characteristics of lateral and vertical GaN transistors are discussed in detail to provide guidance in this complex and interesting field. The second part of the paper focuses on trapping and reliability aspects: the physical origin of traps in GaN and the main degradation mechanisms are discussed in detail. The wide set of referenced papers and the insight into the most relevant aspects gives the reader a comprehensive overview on the present and next-generation GaN electronics