NEW GENERATION OF 3.3 KV IGBTS WITH MONOLITICALLY INTEGRATED VOLTAGE AND CURRENT SENSORS

Although IGBT modules are widely used as power semiconductor switch in many high power applications, there are still reliability problems related to the current unbalance between paralleled IGBTs that may destroy the whole module and, eventually, the power system. Indeed, short-circuit and overvoltage events can also destroy some of the IGBTs of the power module. In this sense, the instantaneous monitoring of the anode current and voltage values and the use of a more intelligent gate driver able to work with the signals of each particular IGBT of the module would enhance its operating lifetime. In this sense, the paper describes the design, optimization, fabrication and basic performances of 3.3 kV – 50 A punch-through IGBTs for traction and tap changer applications where anode current and voltage sensors are monolithically integrated within the IGBT core

Development of a fault tolerant MOS field effect power semiconductor switching transistor

This work describes the development of a semiconductor switch to replace an electromechanical contactor as used within the electrical power distribution system of the More Electric Aircraft (MEA; a project begun in the 1990‟s by the United States Air Force). The MEA is safety critical and therefore requires highest reliability components and systems, but subsequent to a short circuit load fault the electro-mechanical contactor switch often welds shut. This risk is increased when using high discharge energy lithium ion dc batteries. Predominately the semiconductor switch controls inductive loads and is required to safely turn off current of up to 10 times the nominal level during sporadic load fault events. The switch requires the lowest static loss (lowest on state resistance), but also the lowest dynamic loss (losses due to the switching event). Presently, unipolar devices provide the lowest dynamic loss, but bipolar devices provide the lowest static loss. One possible solution is use of a Metal Oxide Semiconductor Field Effect Transistor (MOSFET), the area of which is sized to suit the fault current, but at relatively high cost in terms of silicon area. The resultant area is typically achieved by several die connected in parallel, unfortunately, such a solution suffers from current share imbalance and the potential of cascade die failure. The use of a parallel combination of unipolar and bipolar device types (MOSFET and Insulated Gate Bipolar Transistors, IGBTs) to form a hybrid appears to offer the potential to reduce the silicon area, and static loss, whilst reducing the impact of the increased dynamic losses of the IGBT. Unfortunately, this goal requires optimised gate timing of the resultant hybrid which proves challenging if the load current is to be shared appropriately during fault switching in order to prevent failure. Some form of single MOS (Metal Oxide Semiconductor) gated integrated hybrid device with self biased bipolar injection is therefore required to ensure highest reliability through a non latching design which offers lowest losses under all conditions and achieves an even temperature distribution. In this work the novel concept of the integrated hybrid device has been investigated at a low Blocking Voltage (BV) rating of 100 V, using computer simulation. The three terminal hybrid silicon DMOS (Double diffused Metal Oxide Semiconductor) device utilises a novel merged Schottky p-type injector to provide self biased entry into a reduced static loss bipolar state in the event of high fault current. The device achieves a specific on state resistance, R(ON,SP) = 1.16 mΩcm2 in bipolar mode (with BV=84 V), that is below the silicon limit line and requires half the area of a traditional unipolar MOSFET to conduct fault current. During comparative standard unclamped inductive switching trials, the hybrid device provides a self clamping action which enables increased inductive energy switching (higher inductance and/or higher load current), relative to that achieved by either the MOSFET or IGBT. The hybrid conducting in bipolar mode switches an inductive load off much faster than that typically achieved by an IGBT (toff =20 ns, in comparison to typically >10 μs for an IGBT). This results in a low turn off energy for the hybrid (1.26*10-4 J/cm2) as compared to that of the IGBT (8.72*10-3 J/cm2). The hybrid dynamic performance is enhanced by the action of the merged Schottky contact which, unlike the IGBT, acts to limit the emitter base voltage (VEB) of the internal PNP Bipolar Junction Transistor, BJT (the integral PNP BJT is otherwise a shared feature with the IGBT). The self biased bipolar activation is achieved at a forward bias (VAK) =1.3 V at temperature (T)= 300 K. The device is latch up free across the operational temperature range of T=233 K to 400 K. A viable charge balanced structure to increase the BV rating to approximately 600 V is also proposed. The resulting performance of the single gated, self biased, hybrid, utilising a novel merged Schottky/P type injector, could lead to a new class of rugged MOS gated power switching devices in silicon and potentially silicon carbide

Wide Bandgap Based Devices: Design, Fabrication and Applications, Volume II

Wide bandgap (WBG) semiconductors are becoming a key enabling technology for several strategic fields, including power electronics, illumination, and sensors. This reprint collects the 23 papers covering the full spectrum of the above applications and providing contributions from the on-going research at different levels, from materials to devices and from circuits to systems

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

Miniaturized Transistors, Volume II

In this book, we aim to address the ever-advancing progress in microelectronic device scaling. Complementary Metal-Oxide-Semiconductor (CMOS) devices continue to endure miniaturization, irrespective of the seeming physical limitations, helped by advancing fabrication techniques. We observe that miniaturization does not always refer to the latest technology node for digital transistors. Rather, by applying novel materials and device geometries, a significant reduction in the size of microelectronic devices for a broad set of applications can be achieved. The achievements made in the scaling of devices for applications beyond digital logic (e.g., high power, optoelectronics, and sensors) are taking the forefront in microelectronic miniaturization. Furthermore, all these achievements are assisted by improvements in the simulation and modeling of the involved materials and device structures. In particular, process and device technology computer-aided design (TCAD) has become indispensable in the design cycle of novel devices and technologies. It is our sincere hope that the results provided in this Special Issue prove useful to scientists and engineers who find themselves at the forefront of this rapidly evolving and broadening field. Now, more than ever, it is essential to look for solutions to find the next disrupting technologies which will allow for transistor miniaturization well beyond silicon’s physical limits and the current state-of-the-art. This requires a broad attack, including studies of novel and innovative designs as well as emerging materials which are becoming more application-specific than ever before

Deposição de filmes do diamante para dispositivos electrónicos

This PhD thesis presents details about the usage of diamond in electronics. It presents a review of the properties of diamond and the mechanisms of its growth using hot filament chemical vapour deposition (HFCVD). Presented in the thesis are the experimental details and discussions that follow from it about the optimization of the deposition technique and the growth of diamond on various electronically relevant substrates. The discussions present an analysis of the parameters typically involved in the HFCVD, particularly the pre-treatment that the substrates receive- namely, the novel nucleation procedure (NNP), as well as growth temperatures and plasma chemistry and how they affect the characteristics of the thus-grown films. Extensive morphological and spectroscopic analysis has been made in order to characterise these films.Este trabalho discute a utilização de diamante em aplicações electrónicas. É apresentada uma revisão detalhada das propriedades de diamante e dos respectivos mecanismos de crescimento utilizando deposição química a partir da fase vapor com filament quente (hot filament chemical vapour deposition - HFCVD). Os detalhes experimentais relativos à otimização desta técnica tendo em vista o crescimento de diamante em vários substratos com relevância em eletrónica são apresentados e discutidos com detalhe. A discussão inclui a análise dos parâmetros tipicamente envolvidos em HFCVD, em particular do pré-tratamento que o substrato recebe e que é conhecido na literatura como "novel nucleation procedure" (NNP), assim como das temperaturas de crescimento e da química do plasma, bem como a influência de todos estes parâmetros nas características finais dos filmes. A caracterização morfológica dos filmes envolveu técnicas de microscopia e espetroscopia.Programa Doutoral em Engenharia Eletrotécnic

Intelligent Circuits and Systems

ICICS-2020 is the third conference initiated by the School of Electronics and Electrical Engineering at Lovely Professional University that explored recent innovations of researchers working for the development of smart and green technologies in the fields of Energy, Electronics, Communications, Computers, and Control. ICICS provides innovators to identify new opportunities for the social and economic benefits of society.　 This conference bridges the gap between academics and R&D institutions, social visionaries, and experts from all strata of society to present their ongoing research activities and foster research relations between them. It provides opportunities for the exchange of new ideas, applications, and experiences in the field of smart technologies and finding global partners for future collaboration. The ICICS-2020 was conducted in two broad categories, Intelligent Circuits & Intelligent Systems and Emerging Technologies in Electrical Engineering

3.3 kV PT-IGBT with voltage-sensor monolithically integrated

An intelligent insulated gate bipolar transistor (IGBT) suitable to be used in remote-controlled on-load tap changers and traction applications is analysed in this study. An anode voltage sensor monolithically integrated in the active area of a 3.3 kV-50 A PT-IGBT is introduced to enhance the robustness of the IGBT against short-circuit events. The operation mode of the anode voltage sensor is described and TCAD simulations are performed to describe the static and dynamic performance together with the interaction between the sensor and the IGBT core cells. The study of the anode voltage performance under inductive turn-off conditions is also included, comparing the behaviour of IGBTs with and without anode voltage sensor.Peer Reviewe