Impact of sidewall etching on the dynamic performance of GaN-on-Si E-mode transistors

Abstract The aim of this paper is to investigate the role of the etching of the sidewalls of p-GaN on the dynamic performance of normally-off GaN HEMTs with p-type gate. We analyze two wafers having identical epitaxy but with different recipes for the sidewall etching, referred to as "Etch A" (non-optimized) and "Etch B" (optimized). We demonstrate the following relevant results: (i) the devices with non-optimized etching (Etch A), when submitted to positive gate bias, show a negative threshold voltage shift and a decrease in Ron, which are ascribed to hole injection under the gate and/or in the access regions; (ii) transient characterization indicates the existence of two trap states, with activation energies of 0.84 eV (CN defects) and 0.30 eV. The latter (with time-constants in the ms range) is indicative of the hole de-trapping process, possibly related to trap states in the AlGaN barrier or at the passivation/AlGaN interface; (iii) by optimizing the p-GaN sidewall etching (for the same epitaxy) it is possible to completely eliminate the threshold voltage shift. This indicates that hole injection mostly takes place along the sidewalls

AlGaN/GaN-based power semiconductor switches

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2013.Cataloged from PDF version of thesis.Includes bibliographical references (p. 209-219).AlGaN/GaN-based high-electron-mobility transistors (HEMTs) have great potential for their use as high efficiency and high speed power semiconductor switches, thanks to their high breakdown electric field, mobility and charge density. The ability to grow these devices on large-diameter Si wafers also reduces device cost and makes them easier for wide market adoption. However, the development of AlGaN/GaN-based power switches has encountered three major obstacles: the limited breakdown voltage of AlGaN/GaN transistors grown on Si substrates; the low performance of normally-off AlGaN/GaN transistors; and the degradation of device performance under high voltage pulsed conditions. This thesis studies these issues and presents new approaches to address these obstacles. The first part of the thesis studies the breakdown mechanism in AlGaN/GaN-on-Si transistors. A new quantitative model-trap-limited space-charge impact-ionization model- is developed. Based on this model, a set of design rules is proposed to improve the breakdown voltage of AlGaN/GaN-on-Si transistors. New technologies have also been demonstrated to increase the breakdown voltage of AlGaN/GaN-on-Si transistors beyond 1500 V. The second part of the thesis presents three technologies to improve the performance of normally-off AlGaN/GaN transistors. First, a dual-gate normally-off MISFET achieved high threshold voltage, high current and high breakdown voltage simultaneously by using an integrated cascode structure. Second, a tri-gate AlGaN/GaN MISFET demonstrated the highest current on/off ratio in normally-off GaN transistors with the enhanced electrostatic control from a tri-gate structure. Finally, a new etch-stop barrier structure is designed to address low channel mobility, high interface density and non-uniformity issues associated with the conventional gate recess technology. Using this new structure, normally-off MISFETs demonstrated high uniformity, steep sub-threshold slope and a record channel effective mobility. The thesis concludes with a new dynamic on-resistance measurement technique. With this method, the hard- and soft-switching characteristics of GaN transistors were measured for the first time.by Bin Lu.Ph.D

Wide Bandgap Based Devices

Emerging wide bandgap (WBG) semiconductors hold the potential to advance the global industry in the same way that, more than 50 years ago, the invention of the silicon (Si) chip enabled the modern computer era. SiC- and GaN-based devices are starting to become more commercially available. Smaller, faster, and more efficient than their counterpart Si-based components, these WBG devices also offer greater expected reliability in tougher operating conditions. Furthermore, in this frame, a new class of microelectronic-grade semiconducting materials that have an even larger bandgap than the previously established wide bandgap semiconductors, such as GaN and SiC, have been created, and are thus referred to as “ultra-wide bandgap” materials. These materials, which include AlGaN, AlN, diamond, Ga2O3, and BN, offer theoretically superior properties, including a higher critical breakdown field, higher temperature operation, and potentially higher radiation tolerance. These attributes, in turn, make it possible to use revolutionary new devices for extreme environments, such as high-efficiency power transistors, because of the improved Baliga figure of merit, ultra-high voltage pulsed power switches, high-efficiency UV-LEDs, and electronics. This Special Issue aims to collect high quality research papers, short communications, and review articles that focus on wide bandgap device design, fabrication, and advanced characterization. The Special Issue will also publish selected papers from the 43rd Workshop on Compound Semiconductor Devices and Integrated Circuits, held in France (WOCSDICE 2019), which brings together scientists and engineers working in the area of III–V, and other compound semiconductor devices and integrated circuits

Design, Fabrication and Characterization of GaN HEMTs for Power Switching Applications

The unique properties of the III-nitride heterostructure, consisting of gallium nitride (GaN), aluminium nitride (AlN) and their ternary compounds (e.g. AlGaN, InAlN), allow for the fabrication of high electron mobility transistors (HEMTs). These devices exhibit high breakdown fields, high electron mobilities and small parasitic capacitances, making them suitable for wireless communication and power electronic applications. In this work, GaN-based power switching HEMTs and low voltage, short-channel HEMTs were designed, fabricated, and characterized.In the first part of the thesis, AlGaN/GaN-on-SiC high voltage metal-insulator-semiconductor (MIS)HEMTs fabricated on a novel ‘buffer-free’ heterostructure are presented. This heterostructure effectively suppresses buffer-related trapping effects while maintaining high electron confinement and low leakage currents, making it a viable material for high voltage, power electronic HEMTs. This part of the thesis covers device processing techniques to minimize leakage currents and maximize breakdown voltages in these ‘buffer-free’ MISHEMTs. Additionally, a recess-etched, Ta-based, ohmic contact process was utilized to form low-resistive ohmic contacts with contact resistances of 0.44-0.47 Ω∙mm. High voltage operation can be achieved by employing a temperature-stable nitrogen implantation isolation process, which results in three-terminal breakdown fields of 98-123 V/μm. By contrast, mesa isolation techniques exhibit breakdown fields below 85 V/μm and higher off-state leakage currents. Stoichiometric low-pressure chemical vapor deposition (LPCVD) SiNx passivation layers suppress gate currents through the AlGaN barrier below 10 nA/mm over 1000 V, which is more than two orders of magnitude lower compared to Si-rich SiNx passivation layers. A 10% dynamic on-resistance increase at 240 V was measured in HEMTs with stoichiometric SiNx passivation, which is likely caused by slow traps with time constants over 100 ms. SiNx gate dielectrics display better electrical isolation at high voltages compared to HfO2 and Ta2O5. However, the two gate oxides exhibit threshold voltages (Vth) above -2 V, making them a promising alternative for the fabrication of recess-etched normally-off MISHEMTs.Reducing the gate length (Lg) to minimize losses and increase the operating frequency in GaN HEMTs also entails more severe short-channel effects (SCEs), limiting gain, output power and the maximum off-state voltage. In the second part of the thesis, SCEs were studied in short-channel GaN HEMTs using a drain-current injection technique (DCIT). The proposed method allows Vth to be obtained for a wide range of drain-source voltages (Vds) in one measurement, which then can be used to calculate the drain-induced barrier lowering (DIBL) as a rate-of-change of Vth with respect to Vds. The method was validated using HEMTs with a Fe-doped GaN buffer layer and a C-doped AlGaN back-barrier with thin channel layers. Supporting technology computer-aided design (TCAD) simulations indicate that the large increase in DIBL is caused by buffer leakage. This method could be utilized to optimize buffer design and gate lengths to minimize on-state losses and buffer leakage currents in power switching HEMTs

GaN-on-Si 기반의 고주파/고전력 소자의 제작 및 특성 분석

학위논문 (박사)-- 서울대학교 대학원 : 전기·정보공학부, 2016. 2. 서광석.Owing to the unique capabilities of achieving high current density, high breakdown voltage, high cut-off frequency and high operating temperature, AlGaN/GaN high electron mobility transistors (HEMTs) are emerging as promising candidates for RF power amplifier and power switching devices. Nevertheless, despite the great potential of these new technologies, they still suffer from physical and fabrication issues which may prevent devices fabricated on GaN from achieving the performance required. This thesis presents a comprehensive study on the development of GaN-based high frequency, high power transistors. This work can be divided into two parts, namely D-mode AlGaN/GaN schottky HEMTs on silicon substrate for high power X-band operation and E-mode Si3N4/AlGaN/GaN metal-insulator-semiconductor heterostructure field-effect transistors (MIS-HFETs) for power switching devices. One of the main obstacle is the trapping effects, may be exacerbated when devices are operated in Radar systems. In this work, we will use a novel fluoride-based plasma treatment technique to reduce trapping phenomenon which originated from the surface, and then apply this treatment technique in conjunction with a field plate structure to a device for GaN-based RF applications. To improve overall device performance, a backend process with individually grounded source via formation has been developed to integrate large periphery devices. Based upon it, GaN HEMT amplifier with single chip of 3.6 mm gate periphery has been successfully developed. It exhibits very high power density of 8.1 W/mm with 29.4 W output power under VDS = 38 V pulse operating condition. Compared to the conventional depletion-mode AlGaN/GaN (D-mode), Enhancement mode (E-mode) devices are attracting a great interest as they allow simplistic circuity and safe operation. It is difficult to obtain E-mode operation with a low on-resistance and a high breakdown voltage. A gate recess technique will be crucial to realize an enhancement-mode operation and improve the transfer characteristics. To reduce the on resistance and enhance the drain current density, partially recessed MIS-HFETs are investigated. The gate recess was carried out using a low-damage Cl2/BCl3-based RIE where the target etch depth was remains AlGaN barrier layer in order to improve the transfer characteristics. The occurring degradation of the mobility due to plasma etching-induced damage and scattering effect were effectively removed by partial gate recess technique. The technologies we developed have helped to give definitive direction in developing GaN-based high frequency, high power transistors.CHAPTER 1 Introduction 1 1.1 Background 1 1.2 Substrate for Epitaxial Growth of GaN 6 1.3 Research Aims and Objectives 8 1.4 Organization of Thesis 9 1.5 References 11 CHAPTER 2 Technology Development and Fabrication of AlGaN/GaN HEMTs on Si substrate 15 2.1 Introduction 15 2.2 Epitaxy Layer Structure 16 2.3 Device Fabrication Processes 17 2.3.1 Sample Preparation 18 2.3.2 Mesa Isolation 19 2.3.3 Ohmic Formation 20 2.3.4 Schottky Contacts 24 2.3.5 Contac Pads 26 2.3.6 Air-bridge Interconnection 26 2.4 References 33 CHAPTER 3 Au-Plated Through-Wafer Vias for AlGaN/GaN HEMTs on Si substrate 36 3.1 Introduction 36 3.2 Via-hole Fabrication 37 3.2.1 Experiments 38 3.2.2 Tapered Source Via Formation 40 3.2.3 GaN Etching Process 50 3.2.4 Au Electroplating 53 3.3 Back-side Process Flows 54 3.3.1 Individual Source Via 58 3.3.2 Au-Sn Eutectic Solder Die Attach 60 3.3.3 Thermal Resistance Measurement 61 3.4 References 66 CHAPTER 4 AlGaN/GaN HEMTs for RF applications 69 4.1 Introduction 69 4.2 Advantages of AlGaN/GaN HEMTs for RF Power Devices 70 4.3 RF Performance Limitations 73 4.3.1 Surface States 73 4.3.2 Current Collapse Phenomenon 75 4.4 Device Fabrication 79 4.4.1 Device Layout 85 4.4.2 Slant Gate Process 86 4.4.3 Fluorine Plasma Treatment process 89 4.5 Device Characterization 93 4.5.1 DC and Small Signal Performance 93 4.5.2 Pulse Characteristics 98 4.5.3 Large Signal Performance 99 4.6 Wide Periphery Devices 103 4.6.1 Large Signal Performance 104 4.7 Summary 109 4.8 Reference 110 CHAPTER 5 AlGaN/GaN HEMTs for Power applications 115 5.1 Introduction 115 5.2 Advantages of AlGaN/GaN HEMTs for Power Switching Devices 116 5.2.1 Enhancement-mode Operation 117 5.2.2 High Breakdown Voltage 119 5.3 Device Fabrication 121 5.3.1 Gate Recess Process 124 5.3.2 Plasma Enhance ALD SiNx Film 138 5.4 Characterization for Normally-off GaN Transistors 140 5.4.1 DC Characteristics 140 5.4.2 Breakdown Voltage Characteristics 144 5.4.3 Dynamic Ron Characteristics 146 5.5 Summary 148 5.6 Reference 149 CHAPTER 6 Conclusions and Future Works 155 6.1 Conclusions and Future Works 155 Appendix 159 Abstract in Korean 169 Research Achievements 174Docto

Conception et fabrication de FinFET GaN verticaux de puissance normalement bloqués

Abstract: The tremendous demands for high-performance systems driven by economic constraints forced the semiconductor industry to considerably scale the device's dimensions to compensate for the relatively modest Silicon physical properties. Those limitations pave the way for III-V semiconductors, which are excellent alternatives to Silicon and can be declined in many compositions. For example, Gallium Nitride (GaN) has been considered a fabulous competitor to facilitate the semiconductor industry's horizon beyond the performance limitations of Silicon due to its high mobility, wide bandgap, and high thermal conductivity properties for T>300K (Bulk GaN). It promises to trim the losses in power conversion circuits and drive a 10 % reduction in power consumption. Both lateral and vertical structures have been considered for GaN power devices. The AlGaN/GaN HEMT device's immense potential comes from the high density, high mobility electron gas formed at its heterojunction. The device is vulnerable to reliability issues resulting from the frequent exposure to high electric field collapse, temperature, and stress conditions, thus limiting its performance and reliability. Contrariwise, the vertical GaN power devices have attracted much attention because of the potential to reach high voltage and current levels without enlarging the chip's size. Furthermore, such vertical devices show superior thermal performance to their lateral counterparts. Meanwhile, Vertical GaN devices have the challenges of high leakage current and the breakdown occurring at the corners of the channel. Another challenge associated with Normally off devices is the lack of an optimized method for eliminating the magnesium diffusion from the p-GaN layer. This thesis has two strategic objectives; Firstly, a Normally-OFF GaN Power FinFET has been designed and optimized to overcome the vertical GaN FinFET challenges. It was done by optimizing the performance parameters such as threshold voltage VTH, high breakdown VBR, and the specific ON-state-resistance RON. Accordingly, the impact of both structural and physical parameters should be incorporated to have an exact optimization process. Afterward, the identification and optimization of a low-cost and high-quality fabrication process for the proposed structure underlined this thesis as the second objective.Les énormes demandes de systèmes à hautes performances motivées par des contraintes économiques ont forcé l'industrie des semi-conducteurs à réduire considérablement les dimensions des dispositifs pour compenser les propriétés physiques relativement modestes du silicium. Ces limitations ouvrent la voie aux semi-conducteurs III-V, qui sont d'excellentes alternatives au silicium et peuvent être déclinés dans de nombreuses compositions. Par exemple, le nitrure de gallium (GaN) a été considéré comme un concurrent fabuleux pour faciliter l'horizon de l'industrie des semi-conducteurs au-delà des limitations de performances du silicium en raison de sa grande mobilité, de sa large bande interdite et de ses propriétés de conductivité thermique élevées pour T>300K (Bulk GaN). Il promet de réduire les pertes dans les circuits de conversion de puissance et de réduire de 10 % la consommation d'énergie. À l'heure actuelle, les structures latérales et verticales ont été considérées pour les dispositifs de puissance en GaN. L'immense potentiel du dispositif HEMT AlGaN/GaN provient du gaz d'électrons à haute densité et à haute mobilité formé au niveau de son hétérojonction. Le dispositif est vulnérable aux problèmes de fiabilité résultant de l'exposition fréquente à des conditions d'effondrement de champ électrique, de température et de contrainte élevés, limitant ainsi ses performances et sa fiabilité. En revanche, les dispositifs de puissance verticaux en GaN ont attiré beaucoup d'attention en raison de leur capacité à atteindre des niveaux de tension et de courant élevés sans augmenter la taille de la puce. De plus, ces dispositifs verticaux présentent des performances thermiques supérieures à leurs homologues latéraux. Par ailleurs, les dispositifs GaN verticaux sont confrontés aux défis d'un courant de fuite élevée et de claquage se produisant aux coins du canal. Un autre défi associé aux dispositifs normalement bloqués est l'absence d'une méthode optimisée pour éliminer la diffusion de magnésium de la couche p-GaN. Cette thèse a deux objectifs stratégiques ; premièrement, un dispositif de puissance FinFET GaN normalement bloqué a été conçu et optimisé pour surmonter les défis du FinFET vertical en GaN. Cela a été fait en optimisant les paramètres de performance tels que la tension de seuil VTH, la tension de claquage VBR et la résistance spécifique à l'état passant RON. En conséquence, l'impact des paramètres structurels et physiques doit être incorporé pour avoir un processus d'optimisation précis. Par la suite, l'identification et l'optimisation d'un processus de fabrication à faible coût et de haute qualité pour la structure proposée à souligner cette thèse comme deuxième objectif

AlN/GaN MOS-HEMTs technology

The ever increasing demand for higher power devices at higher frequencies has prompted much research recently into the aluminium nitride/gallium nitride high electron mobility transistors (AlN/GaN HEMTs) in response to theoretical predictions of higher performance devices. Despite having superior material properties such as higher two-dimensional electron gas (2DEG) densities and larger breakdown field as compared to the conventional aluminium gallium nitride (AlGaN)/GaN HEMTs, the AlN/GaN devices suffer from surface sensitivity, high leakage currents and high Ohmic contact resistances. Having very thin AlN barrier layer of ∼ 3 nm makes the epilayers very sensitive to liquids coming in contact with the surface. Exposure to any chemical solutions during device processing degrades the surface properties, resulting in poor device performance. To overcome the problems, a protective layer is employed during fabrication of AlN/GaN-based devices. However, in the presence of the protective/passivation layers, formation of low Ohmic resistance source and drain contact becomes even more difficult. In this work, thermally grown aluminium oxide (Al2O3) was used as a gate di- electric and surface passivation for AlN/GaN metal-oxide-semiconductor (MOS)-HEMTs. Most importantly, the Al2O3 acts as a protection layer during device processing. The developed technique allows for a simple and effective wet etching optimisation using 16H3PO4:HNO3:2H2O solution to remove Al from the Ohmic contact regions prior to the formation of Al2O3 and Ohmic metallisation. Low Ohmic contact resistance (0.76Ω.mm) as well as low sheet resistance (318Ω/square) were obtained after optimisation. Significant reduction in the gate leakage currents was observed when employing an additional layer of thermally grown Al2O3 on the mesa sidewalls, particularly in the region where the gate metallisation overlaps with the exposed channel edge. A high peak current ∼1.5 A/mm at VGS=+3 V and a current-gain cutoff frequency, fT , and maximum oscillation frequency, fMAX , of 50 GHz and 40 GHz, respectively, were obtained for a device with 0.2 μm gate length and 100 μm gate width. The measured breakdown voltage, VBR, of a two-finger MOS-HEMT with 0.5μm gate length and 100 μm gate width was 58 V. Additionally, an approach based on an accurate estimate of all the small-signal equivalent circuit elements followed by optimisation of these to get the actual element values was also developed for AlN/GaN MOS-HEMTs. The extracted element values provide feedback for further device process optimisation. The achieved results indicate the suitability of thermally grown Al2O3 for AlN/GaN-based MOS-HEMT technology for future high frequency power applications

3D GaN nanoarchitecture for field-effect transistors

The three-dimensionality of 3D GaN field-effect transistors (FETs) provides them with unique advantages compared to their planar counterparts, introducing a promising path towards future FETs beyond Moore's law. Similar to today's Si processor technology, 3D GaN FETs offer multi-gate structures that provide excellent electrostatic control over the channel and enable very low subthreshold swing values close to the theoretical limit. Various concepts have been demonstrated, including both lateral and vertical devices with GaN nanowire (NW) or nanofin (NF) geometries. Outstanding transport properties were achieved with laterally contacted NWs that were grown in a bottom-up approach and transferred onto an insulating substrate. For higher power application, vertical FETs based on regular arrays of GaN nanostructures are particularly promising due to their parallel integration capability and large sidewall surfaces, which can be utilized as channel area. In this paper, we review the current status of 3D GaN FETs and discuss their concepts, fabrication techniques, and performances. In addition to the potential benefits, reliability issues and difficulties that may arise in complex 3D processing are discussed, which need to be tackled to pave the way for future switching applications

Design and performance analysis of Tri-gate GaN HEMTs

GaN-based high electron mobility transistors (HEMT) are promising devices for radio frequency (RF) and high-power electronics and are already in use for RF power amplifiers and for power switches. Commonly, these devices are normally-on transistors, i.e., they are in the on-state at zero applied gate voltage, what limits their suitability for various applications, such as fail-safe power switches and RF amplifiers with single-polarity power supply. Unfortunately, in contrast to GaAs- and InP HEMTs, achieving normally-off operation, i.e., a positive thresh-old voltage, for GaN heterostructures is difficult due to the high density of the polarization-induced two-dimensional electron gas (2DEG) at the barrier/buffer interface. For fast RF HEMTs, short gates are required. However, HEMTs with aggres-sively scaled gate length frequently suffer from short-channel effects caused by a degraded control of the gate over the channel. This leads to a deterioration of the transistors off-state performance (increased subthreshold swing and drain-induced barrier lowering) and on-state behavior (increased drain conductance). The tri-gate design has recently been applied to MOSFETs and HEMTs to improve the gate control and suppress short channel effects. Experimental tri-gate transistors show excellent down-scaling characteristics, improved performance, and, in particular for GaN tri-gate HEMTs, a significant shift of the threshold voltage toward positive values. On the other hand, tri-gate GaN normally-off HEMTs are still suffering from increased parasitics causing degraded RF performance (particularly in terms of cutoff frequency) compared to their planar counterparts. Improving the RF performance of GaN tri-gate HEMTs by reducing the parasitics is essential, but this requires a deep understanding of device physics and a thorough analysis of the root causes. In the present work, in-depth theoretical investigations of GaN tri-gate HEMT operation are performed and extensive simulation studies for these devices are conducted. As a result of these efforts, improved insights in the physics of GaN tri-gate HEMTs are achieved, the potential of this transistor type is assessed, design guidelines are elaborated, and advantageous designs are developed. It is shown that the 2DEG sheet density decreases by shrinking the body width, that the threshold voltage of GaN tri-gate HEMTs strongly depends on the width of AlGaN/GaN bodies, and that solely by decreasing the body width a transition from normally-on to normally-off operation can be achieved. The separation between adjacent bodies is shown to have less impact on threshold voltage. The results also show that for wide bodies (> 200 nm) the channel is controlled by both the top-gate and the sidewall gates, while for decreasing body width the control by top-gate gradually diminishes and the channel will be only controlled by side-gates. Furthermore, the impact of AlGaN barrier design (Al content, thickness) is studied, and the results show a limited dependency of the threshold voltage on the barrier design for very narrow bodies. The tri-gate concept enables normally-off operation, provides improved on-state performance (higher transconductance), and effectively suppresses short-channel effects in the off-state. Moreover, the simulation results show that GaN tri-gate HEMTs can exhibit higher breakdown voltages and operate closer to the theoretical limit for GaN devices than their planar counterparts. Moreover, the simulations indicate that the RF performance of GaN tri-gate HEMTs with optimized body designs can be superior to that of conventional planar devices. A means to improve the RF performance is the reduction of the body etch height, leading to a decreased parasitic coupling between the sidewalls and the source/drain electrodes. Thus, reducing the body height leads to a decreased overall gate capacitance and an improved RF performance. Another way to reduce the overall gate capacitance is to cover the body sidewalls with a dielectric (e.g. SiN). This reduces the fringing capacitance components since the gap between neighboring bodies that is filled with gate metal is narrower compared to the case without dielectrics. Finally, the polarization charge at the barrier/channel interface and thus the electron density in the 2DEG) can be increased either by increasing the aluminium content of the AlGaN barrier or by using a different barrier material (e.g., lattice matched In0.17 Al0.83 N). In the frame of a joint DFG project, GaN tri-gate HEMTs designed based on the improved insights in the physics of these devices have been fabricated and characterized at Fraunhofer IAF. These devices having a gate length of 100 nm are by far the fastest GaN tri-gate HEMTs worldwide and show record performance in terms of cutoff frequency (120 GHz) and maximum frequency of oscillation (300 GHz).HEMTs (high electron mobility transistors) auf GaN-Basis besitzen großes Potenzial für die HF- (Hochfrequenz) und Leistungselektronik und werden bereits in HF-Leistungsverstärkern und als Leistungsschalter verwendet. Üblicherweise sind GaN HEMTs Normally-On Transistoren (d.h. Transistoren, die sich bei einer Gatespannung von 0 V im Ein-Zustand befinden), was für Anwendungen wie Fail-Safe-Leistungsschalter und HF-Verstärker mit nur einer Versorgungsspannung nachteilig ist. Es schwierig, GaN HEMTs mit Normally-Off-Charakteristik (HEMTs mit positiver Schwellspannung) zu realisieren, da in diesen Transistoren die Dichte des sich an der Grenzfläche Barriere/Puffer ausbildenden 2DEG (zweidimensionales Elektronengas) auf Grund starker Polarisationseffekte erheblich größer als in GaAs und InP HEMTs ist. Die Realisierung schneller HF-HEMTs erfordert kurze Gates. Allerdings leiden Transistoren mit sehr kurzen Gates häufig unter Kurzkanaleffekten und einer reduzierten Steuerwirkung des Gates, was zu einer Verschlechterung des Verhaltens im Aus-Zustand (erhöhte Werte für den Subthreshold Swing und das Drain-Induced Barrier Low-ering) und im Ein-Zustand (erhöhter Drainleitwert) führt. In jüngster Zeit wird bei MOSFETs und HEMTs das Tri-Gate-Design angewendet, um die Gatesteuerwirkung zu verbessern und Kurzkanaleffekte zu unterdrücken. So wurden bereits Tri-Gate-Transistoren mit ausgezeichnetem Skalierungsverhalten, verbesserten Eigenschaften und, speziell im Fall von GaN Tri-Gate-HEMTs, positiver Schwellspannung, demonstriert. Auf der anderen Seite leiden GaN Tri-Gate-HEMTs mit Normally-Off-Charakteristik jedoch unter großen Parasitäten, die das HF-Verhalten (insbesondere die Transitfrequenz) beeinträchtigen. Die Verbesserung des HF-Verhaltens und eine Reduzierung der Parasitäten von GaN Tri-Gate-HEMTs ist daher dringend nötig. Das erfordert jedoch ein tiefes Eindringen in die Physik dieser Bauelemente. In der vorliegenden Arbeit werden umfassende theoretische Untersuchungen und Bauelementesimulationen zu GaN Tri-Gate-HEMT beschrieben, die zu einem deutlichen verbesserten Verständnis der Wirkungsweise von GaN Tri-Gate-HEMTs führten. So konnten das Potential dieses Transistortyps bewertet, Designregeln erarbeitet und vorteilhafte Transistordesigns entwickelt werden. In der Arbeit wird gezeigt, dass eine Verringerung der Bodyweite bei gegebener Gatespannung zu einer Verringerung der Ladungsträgerdichte im 2DEG führt, dass die Schwellspannung maßgeblich von der Bodyweite bestimmt wird und dass bei hinreichend geringer Bodyweite der Übergang vom Normall-On- zum Normally-Off-Betrieb erfolgt. Es wird auch gezeigt, dass der Abstand zwischen benachbarten Bodies nur einen geringen Einfluss auf die Schwellspannung hat. Darüber hinaus wird demonstriert, dass im Fall weiter Bodies (> 200 nm) der Kanal sowohl durch das Top-Gate als auch durch die Seiten-Gates gesteuert wird, während bei schmaleren Bodies die Steuerwirkung durch das Top-Gate geringer wird und die Verhältnisse im Kanal im Wesentlichen durch das Seiten-Gates bestimmt werden. In der Arbeit wird weiterhin Rolle des Designs der AlGaN-Barriere (Al-Gehalt, Dicke) untersucht und demonstriert, dass die Gestaltung der Barriere bei schmalen Bodies nur einen begrenzten Einfluss auf die Schwellspannung hat. Die Untersuchungen zeigen deutlich, dass das mit dem Tri-Gate-Konzept Normally-Off-Transistoren realisierbar sind, dass das Transistorverhalten im Ein-Zustand verbessert (höhere Steilheit) wird, und dass Kurzkanaleffekte im Aus-Zustand wirkungsvoll unterdrückt. Es wird auch demonstriert, dass GaN Tri-Gate HEMTs höhere Durchbruchspannungen zeigen und näher an der theoretischen Grenze für GaN-Bauelemente arbeiten als planare GaN HEMTs. Ein weiteres Ergebnis der vorliegenden Arbeit ist der Nachweis, dass GaN Tri-Gate-HEMTs mit sorgfältig optimiertem Design den planaren HEMTs auch hinsichtlich des HF-Verhaltens überlegen sind. Ein Mittel zur Verbesserung des HF-Verhaltens ist die Reduzierung der Body-Ätzhöhe, die zur Verringerung der parasitären Kopplung zwischen den Body-Seitenwänden und den Source/Drain-Elektroden und somit zu einer geringeren Gatekapazität führt. Eine weitere Maßnahme zur Reduzierung der Gatekapazität ist die Beschichtung der Body-Seitenwände mit einem Dielektrikum (z.B. SiN). Das verringert die Streukapazität, da jetzt die mit dem Gatemetall gefüllte Lücken zwischen benachbarten Bodies schmaler sind. Schließlich wird gezeigt, dass die Polarisationsladung an der Grenzfläche Barrier/Kanal und somit die Elektronendichte im 2DEG durch Erhöhung des Al-Gehalts der AlGaN-Barriere oder durch Nutzung eines anderen Materials für die Barriere (z.B. gitterangepasstes In0.17 Al0.83 N) gesteigert werden kann

Vertical Gallium Nitride Power Devices: Fabrication and Characterisation

Efficient power conversion is essential to face the continuously increasing energy consumption of our society. GaN based vertical power field effect transistors provide excellent performance figures for power-conversion switches, due to their capability of handling high voltages and current densities with very low area consumption. This work focuses on a vertical trench gate metal oxide semiconductor field effect transistor (MOSFET) with conceptional advantages in a device fabrication preceded GaN epitaxy and enhancement mode characteristics. The functional layer stack comprises from the bottom an n+/n- drift/p body/n+ source GaN layer sequence. Special attention is paid to the Mg doping of the p-GaN body layer, which is a complex topic by itself. Hydrogen passivation of magnesium plays an essential role, since only the active (hydrogen-free) Mg concentration determines the threshold voltage of the MOSFET and the blocking capability of the body diode. Fabrication specific challenges of the concept are related to the complex integration, formation of ohmic contacts to the functional layers, the specific implementation and processing scheme of the gate trench module and the lateral edge termination. The maximum electric field, which was achieved in the pn- junction of the body diode of the MOSFET is estimated to be around 2.1 MV/cm. From double-sweep transfer measurements with relatively small hysteresis, steep subthreshold slope and a threshold voltage of 3 - 4 V a reasonably good Al2O3/GaN interface quality is indicated. In the conductive state a channel mobility of around 80 - 100 cm2/Vs is estimated. This obtained value is comparable to device with additional overgrowth of the channel. Further enhancement of the OFF-state and ON-state characteristics is expected for optimization of the device termination and the high-k/GaN interface of the vertical trench gate, respectively. From the obtained results and dependencies key figures of an area efficient and competitive device design with thick drift layer is extrapolated. Finally, an outlook is given and advancement possibilities as well as technological limits are discussed.:1 Motivation and boundary conditions 1.1 A comparison of competitive semiconductor materials 1.2 Vertical GaN device concepts 1.3 Target application for power switches 2 The vertical GaN MOSFET concept 2.1 Incomplete ionization of dopants 2.2 The pseudo-vertical approach 2.3 Considerations for the device OFF-state 2.3.1 The pn-junction in reverse operation 2.3.2 The gate trench MIS-structure in OFF-state 2.3.3 Dimensional constraints and field plates 2.4 Static ON-state and switching considerations 2.4.1 The pn-junction in forward operation 2.4.2 Resistance contributions 2.4.3 Device model and channel mobility 2.4.4 Threshold voltage and subthreshold slope 2.4.5 Interface and dielectric trap states in wide band semiconductors 2.4.6 The body bias effect 3 Fabrication and characterisation 3.1 Growth methods for GaN substrates and layers 3.2 Substrates and the desired starting material 3.2.1 Physical and micro-structural characterisation 3.2.2 Dislocations and impurities 3.3 Pseudo- and true-vertical MOSFET fabrication 3.3.1 Processing routes 3.3.2 Inductively-coupled plasma etching 3.3.3 Process flow modification 3.4 Electrical characterisation, structures and process control 3.4.1 Current voltage characterisation 3.4.2 C(V) measurements and charge carrier profiling 3.4.3 Cooperative characterisation structures 4 Properties of the functional layers 4.1 Morphology of the MOVPE grown layers 4.2 Hydrogen out-diffusion treatment 4.3 Morphology of the n+-source layer grown by MBE 4.4 N-type doping of the functional layers 4.5 P-type GaN by magnesium doping 4.6 Structural properties after the etching and gate module formation 4.7 Electrical layer characterization 4.7.1 Gate dielectric and interface evaluation 5 Pseudo- and true vertical device operation 5.1 Influences of the metal-line sheet resistance 5.2 Formation and characterisation of ohmic contacts 5.2.1 Ohmic contacts to n-type GaN 5.2.2 Ohmic contacts to p-GaN 5.3 The pn- body diode 5.4 MOSFET operation 5.4.1 ON-state and turn-ON operation 5.4.2 The body bias effect on the threshold voltage 5.4.3 Device OFF-state 6 Summary and conclusion 6.1 Device performance 6.2 Current limits of the vertical device technology 6.3 Possibilities for advancements Bibliography A Appendix A.1 Deduction: Forward diffusion current of the pn-diode A.2 Deduction: Operation regions in the EKV model Figures Tables Abbreviations Symbols Postamble and Acknowledgemen