The epitaxial layer design of HEMTs

Morton, Christopher Gordon

January 1994

No description available.

621.31042

Computerized evaluation of parameters for HEMT DC and microwave S parameter models

Chen, Lu

January 1995

No description available.

High Electron Mobility Transistor

Microwave S Parameter

Aluminum-Gallium-Arsenium

Design, Fabrication and Characterization of InAlAs/InGaAs/InAsP Composite Channel HEMTs

Liu, Dongmin

05 September 2008

No description available.

Electrical Engineering

InP

High electron mobility transistor

InAsP

composite channel

Polymer-Supported Bridges for Multi-Finger AlGaN/GaN Heterojunction Field Effect Transistors (HFETs)

Willemann, Michael Howard

04 September 2007

Current AlGaN/GaN Heterojunction Field Effect Transistors (HFETs) make use of multiple sources, drains, and gates in parallel to maximize transconductance and effective gain while minimizing the current density through each channel. To connect the sources to a common ground, current practice prescribes the fabrication of air bridges above the gates and drains. This practice has the advantage of a low dielectric constant and low parasitic capacitance, but it is at the expense of manufacturability and robust device operation. In the study described below, the air bridges in AlGaN/GaN HFETs were replaced by a polymer supported metallization bridge with the intention of improving ease of fabrication and reliability. The DC, high frequency, and power performance for several polymer step heights were investigated. The resultant structures were functional and robust; however, their electrical performance was degraded due to high source resistance. The cause of the high source resistance was found to be thinning of the metallization at the polymer step. The effect was more pronounced for higher step heights. / Master of Science

Wide-bandgap semiconductor

High Electron Mobility Transistor

RF power electronics

Fabrication of nitride-based high electron mobility transistor biosensor to detect pancreatic cancer antigen

Hsu, Shi-Ya

31 July 2012

Abstract ¡@¡@Biosensor chip has a lot of advantages, such as label-free, ultra-sensitive, highly selective, fast and real-time detection. Fabricating biosensor chip has great benefits for gene-detection, protein-detection, medical diagnosis and development of new medicine. This research will integrate the biomedical, chemistry, and physics, and also combined with biochemical technology and semiconductor technology to produce biosensor chip. ¡@¡@We use microelectronic semiconductor process technology to fabricate silicon nanowire field effect transistors (SiNW-FET). The source-drain current versus the voltage curve (Isd-Vsd) shows that the contact pad and the silicon nanowire form ohmic contact. And then we use chemical surface modification technologies to modified biotin on SiNW-FET to detect streptavidin. ¡@¡@In addition, we also grow AlGaN/GaN film by MBE, and fabricate nitride¡Vbased high electron mobility transistor (HEMT) by microelectronic semiconductor process technology. In this study, we apply HEMT in biosensor for pancreatic cancer marker CA19-9 antigen. And we modify pancreatic cancer marker CA19-9 antibody on the biosensor chip surface to detect pancreatic cancer marker CA19-9 antigen molecule. ¡@¡@Most of biomolecules are with weak charges, which can form chemical gating effect and change the conductance of p-type SiNW. And according to the streptavidin microfluidic measurement of biotin-modified SiNW-FET, the detection limit of streptavidin was 10-9 M. And the detection limit of pancreatic cancer marker CA19-9 antigen for N-HEMT biosensor was 150 U/mL.

silicon nanorod

biotin

field effect transistor

streptavidin

pancreatic cancer

Biosensor

high electron mobility transistor

High Power GaN/AlGaN/GaN HEMTs Grown by Plasma-Assisted MBE Operating at 2 to 25 GHz

Waechtler, Thomas, Manfra, Michael J, Weimann, Nils G, Mitrofanov, Oleg

27 April 2005

Heterostructures of the materials system GaN/AlGaN/GaN were grown by molecular beam epitaxy on 6H-SiC substrates and high electron mobility transistors (HEMTs) were fabricated. For devices with large gate periphery an air bridge technology was developed for the drain contacts of the finger structure. The devices showed DC drain currents of more than 1 A/mm and values of the transconductance between 120 and 140 mS/mm. A power added efficiency of 41 % was measured on devices with a gate length of 1 µm at 2 GHz and 45 V drain bias. Power values of 8 W/mm were obtained. Devices with submicron gates exhibited power values of 6.1 W/mm (7 GHz) and 3.16 W/mm (25 GHz) respectively. The rf dispersion of the drain current is very low, although the devices were not passivated. / Heterostrukturen im Materialsystem GaN/AlGaN/GaN wurden mittels Molekularstrahlepitaxie auf 6H-SiC-Substraten gewachsen und High-Electron-Mobility-Transistoren (HEMTs) daraus hergestellt. Für Bauelemente mit großer Gateperipherie wurde eine Air-Bridge-Technik entwickelt, um die Drainkontakte der Fingerstruktur zu verbinden. Die Bauelemente zeigten Drainströme von mehr als 1 A/mm und Steilheiten zwischen 120 und 140 mS/mm. An Transistoren mit Gatelängen von 1 µm konnten Leistungswirkungsgrade (Power Added Efficiency) von 41 % (bei 2 GHz und 45 V Drain-Source-Spannung) sowie eine Leistung von 8 W/mm erzielt werden. Bauelemente mit Gatelängen im Submikrometerbereich zeigten Leistungswerte von 6,1 W/mm (7 GHz) bzw. 3,16 W/mm (25 GHz). Die Drainstromdispersion ist sehr gering, obwohl die Bauelemente nicht passiviert wurden.

AlGaN

GaN

High Electron Mobility Transistor

MBE

heterostructure

ddc:621

ddc:537

HEMT

Robustness and Stability of Gallium Nitride Transistors in Dynamic Power Switching

Song, Qihao

16 September 2024

Wide-bandgap gallium nitride (GaN) high electron mobility transistors (HEMTs) are gaining increased adoption in applications like mobile electronics and data centers. Benefitting from the high channel mobility and the high breakdown field of GaN, GaN power HEMTs enable low specific on-resistance and small capacitance and thus become attractive for high-frequency applications. In addition, most commercial GaN power HEMTs are fabricated on Si substrates up to 8 inches, allowing for a remarkable cost advantage. However, a by-product of the low-cost GaN-on-Si wafer (and conductive Si substrate) is the high voltage drop and high electric field (E-field) in the GaN buffer layers and transition layers sandwiched between the GaN channel and Si substrate. To boost the vertical blocking capability and minimize the leakage current, the GaN buffer layer is usually doped with carbon or iron, which can introduce complex carrier traps. This can further lead to the dynamic shifts of various parameters in GaN-on-Si HEMTs, which can cause their stability and robustness issues in practical circuit operations. This dissertation work studies the robustness and stability of GaN power HEMTs in dynamic power switching. The structures of most GaN power devices are fundamentally different from Si or Silicon Carbide (SiC) power devices, leading to numerous open questions on GaN power device robustness and stability. Simple equipment-level static characterization may not reflect the real device characteristics in circuit-level operation. Based on the relevance between the stress condition and the device's safe operating area (SOA), this dissertation is divided into two parts. In each part, two representative GaN power devices, the standalone GaN HEMT, and the GaN-Si cascode HEMT, are studied. The dissertation's first half discusses the GaN HEMT behavior outside of SOA, with a focus on the robustness of GaN HEMTs in overvoltage power switching. This focus is motivated by the lack of avalanche capability of GaN HEMTs, which is a unique device physics distinct from SiC/Si power transistors. Instead of withstanding the surge energy through avalanching, GaN HEMTs rely on their high breakdown voltage margin to withstand the surge energy, which can trigger new degradation and failure mechanisms. Therefore, investigating the GaN HEMTs' robustness in overvoltage switching is of great interest. The robustness study begins with a standalone depletion-mode (D-mode) MIS (Metal-Insulator-Semiconductor) HEMT in an overvoltage hard-switching. The device is found to show a decreased threshold voltage and increased saturation current after stress. These parametric shifts increase as switching cycles increase but reach a saturation point before one million cycles. The root cause is believed to be the impact-ionization-generated holes trapped underneath the insulated gate. This is verified by the physics-based TCAD (Technology Computer-Aided Design) simulation. After the stress, MIS-HEMT cannot fully recover naturally. Applying at positive gate-to-source bias (VGS) is found to be able to accelerate the threshold voltage recovery but not the saturation current recovery, while a 50-V substrate bias is shown to fully recover both parameters. These findings provide new insight into the hole trapping/de-trapping dynamics and the benefits of substrate voltage control in GaN MIS-HEMTs. Then, a cascode GaN HEMT, which contains a D-mode GaN MIS-HEMT and an enhancement-mode (E-mode) Si MOSFET, is studied similarly in overvoltage stress produced by an inductive switching circuit. Parametric shifts are found in cascode GaN HEMTs, including the unstable breakdown voltage and increased on-resistance. The crosstalk between Si MOSFET and GaN HEMT is believed to account for these parametric shifts. A decapsulated device is developed based on the commercial part to monitor the Si MOSFET behavior. Si MOSFET is found to avalanche during the overvoltage switching. The parametric shifts are believed to be due to the avalanche-generated electrons, which are injected into the GaN HEMTs and trapped in the GaN buffer layer. These electron traps alter the E-field distribution of the GaN HEMT and induce parametric shifts. The second half of the dissertation focuses on the GaN HEMT's stability inside the SOA, with a focus on the non-ideal power loss generated in high-frequency switching. The output capacitance (COSS) loss has recently been found to be the dominant loss in soft switching, which is the loss associated with GaN HEMT's COSS when it is charged and discharged. This process should be lossless for an ideal capacitor, but GaN HEMT experiences a hysteresis COSS loss during each charging-discharging cycle due to the COSS instability in dynamic power switching. The COSS loss study starts with an accurate and easy-to-implement test platform, which is proven to have good robustness and repeatability. The measured COSS loss of different types of GaN HEMTs is modeled, followed by the investigation of the COSS loss origin. TCAD simulation reveals the fundamental role of trappings in the cause of COSS loss in standalone GaN HEMTs. For the cascode GaN HEMT, two additional loss mechanisms are involved as compared to the standalone GaN HEMTs: Si avalanche energy loss and GaN early turn-on loss. This makes cascode GaN HEMT experiences much higher COSS loss than standalone GaN HEMTs. The COSS loss of cascode GaN HEMT is quantitively analyzed, and a mitigation strategy is proposed for suppressing the COSS loss of cascode GaN HEMTs. Then, a circuit-level method is proposed to reduce the COSS loss of standalone GaN HEMT by dynamically tuning the substrate bias, which is verified with a standalone D-mode GaN HEMT. The Si substrate bias can follow the drain voltage in a certain ratio by tuning the capacitance ratio between the drain, substrate, and source. It is found that with a substrate bias of 1/4 to 1/2 of the drain voltage, the COSS loss can be reduced by 86%. This result removes a critical roadblock for deploying GaN HEMTs in high-frequency, soft-switching applications. Finally, the COSS loss of similarly rated Si and SiC power transistors is characterized using the developed test platform. The capability of the setup is further broadened to testing power diodes. Some similarities and distinctions are found in the COSS loss behavior between GaN HEMTs and Si/SiC devices. Also, an EDISS validation process is provided for the UIS-based method in an operating class-E converter, verifying the effectiveness and accuracy of the proposed method. This provides important references for selecting the optimal power devices for high-frequency applications. / Doctor of Philosophy / Gallium Nitride (GaN) high electron mobility transistors (HEMTs) are reshaping the power electronics field. They have become increasingly popular in many applications like smartphones, electric vehicles, and data centers. They offer smaller on-resistance and can handle higher voltages compared to traditional silicon-based devices. GaN transistors are built on large-diameter silicon substrates, making them cost-effective but can lead to unique stability and robustness issues. This dissertation investigates the stability and robustness of GaN power HEMTs in high-voltage and high-frequency power switching. Based on the relevance of the studied stress to the device safe-operating-area, the discussion is divided into two parts: The first part looks at how GaN transistors handle situations where they are pushed beyond their safe operating limits, such as during power surges and overvoltage events. These transistors are found to experience changes in their electrical properties after being stressed, which might affect their performance across their lifetime. In addition to unveiling the physics and evolution of such parametric shifts, this work also discovers ways to recover the device parameters and maintain the device functionality. The second part of the research focuses on the stability and non-ideal power loss of GaN transistors within their safe operating area. The high-frequency soft-switching application is being investigated, as it has become a common trend for future power electronics. The study reveals that GaN transistors can produce additional power loss due to the intrinsic electrical instabilities. In addition to unveiling the key impact factors and physics of this loss, this work also develops device designs to suppress this non-ideal power loss significantly, improving the device efficiency in high-frequency applications. Overall, this work provides valuable insights into improving the robustness and efficiency of GaN transistors, which provide guidelines and insights for GaN designers and users to achieve optimal device and system performance.

Power Electronics

Power Semiconductor Devices

Wide bandgap

Gallium Nitride

High Electron Mobility Transistor

Robustness

Stability

Low Noise Amplifiers using highly strained InGaAs/InAlAs/InP pHEMT for implementation in the Square Kilometre Array (SKA)

Mohamad Isa, Muammar Bin

January 2012

The Square Kilometre Array (SKA) is a multibillion and a multinational science project to build the world’s largest and most sensitive radio telescope. For a very large field of view, the combined collecting area would be one square kilometre (or 1, 000, 000 square metre) and spread over more than 3,000 km wide which will require a massive count of antennas (thousands). Each of the antennas contains hundreds of low noise amplifier (LNA) circuits. The antenna arrays are divided into low, medium and high operational frequencies and located at different positions to boost up the telescope’s scanning sensitivity.The objective of this work was to develop and fabricate fully on-chip LNA circuits to meet the stringent requirements for the mid-frequency array from 0.4 GHz to 1.4 GHz of the SKA radio astronomy telescope using Monolithic Microwave Integrated Circuit technology (MMIC). Due to the number of LNA reaching figures of millions, the fabricated circuits were designed with the consideration for low cost fabrication and high reliability in the receiver chain. Therefore, a relaxed optical lithography with Lg = 1 µm was adopted for a high yield fabrication process.Towards the fulfilment of the device’s low noise characteristics, a large number of device designs, fabrication and characterisation of InGaAs/InAlAs/InP pHEMTs were undertaken. These include optimisations at each critical fabrication steps. The device’s high breakdown and very low gate leakage characteristics were further improved by a combination of judicious epitaxial growth and manipulation of materials’ energy gaps. An attempt to increase the device breakdown voltage was also employed by incorporating Field Plate structure at the gate terminal. This yielded the devices with improvements in the breakdown voltage up to 15 V and very low gate leakage of 1 µA/mm, in addition to high transconductance (gm) characteristic. Fully integrated double stage LNA had measured NF varying from 1.2 dB to 1.6 dB from 0.4 GHz to 1.4 GHz, compared with a slightly lower NF obtained from simulation (0.8 dB to 1.1 dB) across the same frequency band.These are amongst the attractive device properties for the implementation of a fully on-chip MMIC LNA circuits demonstrated in this work. The lower circuit’s low noise characteristic has been demonstrated using large gate width geometry pHEMTs, where the system’s noise resistance (Rn) has successfully reduced to a few ohms. The work reported here should facilitate the successful implementation of rugged low noise amplifiers as required by SKA receivers.

522

DC, RF, and Thermal Characterization of High Electric Field Induced Degradation Mechanisms in GaN-on-Si High Electron Mobility Transistors

Bloom, Matthew Anthony

01 March 2013

Gallium Nitride (GaN) high electron mobility transistors (HEMTs) are becoming increasingly popular in power amplifier systems as an alternative to bulkier vacuum tube technologies. GaN offers advantages over other III-V semiconductor heterostructures such as a large bandgap energy, a low dielectric constant, and a high critical breakdown field. The aforementioned qualities make GaN a prime candidate for high-power and radiation-hardened applications using a smaller form-factor. Several different types of semiconductor substrates have been considered for their thermal properties and cost-effectiveness, and Silicon (Si) has been of increasing interest due to a balance between both factors. In this thesis, the DC, RF, and thermal characteristics of GaN HEMTs grown on Si-substrates will be investigated through a series of accelerated lifetime experiments. A figure of merit known as the critical voltage is explored and used as the primary means by which the GaN-on-Si devices are electrically strained. The critical voltage is defined as the specific voltage bias by which a sudden change in device performance is experienced due to a deformation of the target GaN HEMT’s epitaxial structure. Literature on the topic details the inevitable formation of pits and cracks localized under the drain-side of the gate contact that promote electrical degradation of the devices via the inverse piezoelectric effect. Characteristic changes in device performance due to high field strain are recorded and physical mechanisms behind observed degraded performance are investigated. The study assesses the performance of roughly 60 GaN-on-Si HEMTs in four experimental settings. The first experiment investigates the critical voltage of the device in the off-state mode of operation and explores device recovery post-stress. The second experiment analyzes alterations in DC and RF performance under varying thermal loads and tracks the dependence of the critical voltage on temperature. The third experiment examines electron trapping within the HEMTs as well as detrapping methodologies. The final experiment links the changes in RF performance induced by high field strain to the small-signal parameters of the HEMT. Findings from the research conclude the existence of process-dependent defects that originate during the growth process and lead to inherent electron traps in unstressed devices. Electron detrapping due to high electric field stress applied to the HEMTs was observed, potentially localized within the AlGaN layer or GaN buffer of the HEMT. The electron detrapping in turn contributed to drain current recovery and increased unilateral performance of the transistor in the RF regime. Thermal experiments resulted in a positive shift in critical voltage, which enhanced gate leakage current at lower gate voltage drives.

GaN

High Electron Mobility Transistor

HEMT

Degradation

Characterization

Critical Voltage

Electrical and Electronics

Semiconductor and Optical Materials

Investigation on Device Characteristics of the InGaAs Pseudomorphic High Electron Mobility Transistors¡GRF I-V Curves and High Frequency Nonlinear Models Establishment

Lee, Yen-Ting

02 September 2010

In this thesis, the investigation focuses on the analysis of the high frequency characteristics and the nonlinearity of the transistors. In view of the III-V semiconductors which have excellent high frequency performance and the advantage for high frequency circuit design, the 0.15£gm InGaAs based pseudomorphic high electron mobility transistors provided by WIN semiconductor Corp. were used in this study. The high frequency measurement was utilized to extract both extrinsic and intrinsic components of the transistors, and further to establish the small signal equivalent model in each bias condition. According to the physical definition of the extracted gm, gds and the relationship with the output current, RF I-V curves could be determined through the integration procedure. The nonlinearity of the transistors can be attributed to the nonlinear input capacitance Cgs and Cgd, and the voltage dependent current source. The high frequency nonlinear models proposed in this thesis were based on classic Angelov model. For the high frequency application, the frequency dependent characteristics of the nonlinear sources would be taken into consideration through the combination of the RF I-V curves and extracted intrinsic components. Thus, the nonlinearities could be able to describe by nonlinear function through the fitting process and model the output performance completely. The accuracy of the models could be confirmed through the comparison between the simulation and the measurement result. Obviously, the high frequency models which include the high frequency effect and the nonlinear characteristics have excellent agreement with the experimental data.

High Frequency Nonlinear Characteristics

Small Signal Models

High Frequency Nonlinear Models

RF I-V Curves