Impact of Gamma Radiation on Dynamic RDSON Characteristics in AlGaN/GaN Power HEMTs

GaN high-electron-mobility transistors (HEMTs) are promising next-generation devices in the power electronics field which can coexist with silicon semiconductors, mainly in some radiation-intensive environments, such as power space converters, where high frequencies and voltages are also needed. Its wide band gap (WBG), large breakdown electric field, and thermal stability improve actual silicon performances. However, at the moment, GaN HEMT technology suffers from some reliability issues, one of the more relevant of which is the dynamic on-state resistance (RON_dyn) regarding power switching converter applications. In this study, we focused on the drain-to-source on-resistance (RDSON) characteristics under 60Co gamma radiation of two different commercial power GaN HEMT structures. Different bias conditions were applied to both structures during irradiation and some static measurements, such as threshold voltage and leakage currents, were performed. Additionally, dynamic resistance was measured to obtain practical information about device trapping under radiation during switching mode, and how trapping in the device is affected by gamma radiation. The experimental results showed a high dependence on the HEMT structure and the bias condition applied during irradiation. Specifically, a free current collapse structure showed great stability until 3.7 Mrad(Si), unlike the other structure tested, which showed high degradation of the parameters measured. The changes were demonstrated to be due to trapping effects generated or enhanced by gamma radiation. These new results obtained about RON_dyn will help elucidate trap behaviors in switching transistors

Fast System to measure the dynamic on‐resistance of on‐wafer 600 V normally off GaN HEMTs in hard‐switching application conditions

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Power Loss Characterization and Modeling for GaN-Based Hard-Switching Half-Bridges Considering Dynamic on-State Resistance

Gallium nitride enhancement-mode high electron mobility transistors (GaN E-HEMTs) can achieve high frequency and high efficiency due to its excellent switching performance compared with conventional Si transistors. Nevertheless, GaN HEMTs exhibit a more pronounced dynamic ON-state resistance R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} than silicon transistors. The variation of R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} is caused by both the static R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} due to junction temperature rise and the dynamic R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} due to the electron trapping. Without a careful decoupling analysis, it is difficult to calculate and model the dynamic R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} portion. This article introduces a comprehensive approach of dynamic R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} evaluation comprising four techniques: 1) a clamping circuit for both the hard-switching (HS) device and synchronous rectification (SR) device; 2) a junction temperature monitoring technique; 3) control of both the pulse test and soak time; and 4) continuous operation of device under test. Based on the dynamic R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} test results, a new model of the R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} variation is developed where two coefficients k-{T{j}} and k-{mathrm {dR}} are defined to model the contribution of the heating effect and the impact of the trapping effect, respectively. The R-{mathrm {DS}(mathrm{scriptscriptstyle ON})} model is validated by the comparison between the calculated and measured junction temperatures of a 650-V/30-A GaN-based half-bridge. Furthermore, a detailed loss breakdown analysis is conducted for the GaN-based HS half-bridge. The results show that the switching losses, E-{mathrm{scriptscriptstyle ON}} and E-{mathrm{scriptscriptstyle OFF}} , are the dominant loss factors with high switching frequency. At last, the possible efficiency improvements are also discussed in detail

STUDY OF RADIATION EFFECTS IN GAN-BASED DEVICES

Radiation tolerance of wide-bandgap Gallium Nitride (GaN) high-electron-mobility transistors (HEMT) has been studied, including X-ray-induced TID effects, heavy-ion-induced single event effects, and neutron-induced single event effects. Threshold voltage shift is observed in X-ray irradiation experiments, which recovers over time, indicating no permanent damage formed inside the device. Heavy-ion radiation effects in GaN HEMTs have been studied as a function of bias voltage, ion LET, radiation flux, and total fluence. A statistically significant amount of heavy-ion-induced gate dielectric degradation was observed, which consisted of hard breakdown and soft breakdown. Specific critical injection level experiments were designed and carried out to explore the gate dielectric degradation mechanism further. Transient device simulations determined ion-induced peak transient electric field and duration for a variety of ion LET, ion injection locations, and applied drain voltages. Results demonstrate that the peak transient electric fields exceed the breakdown strength of the gate dielectric, leading to dielectric defect generation and breakdown. GaN power device lifetime degradation caused by neutron irradiation is reported. Hundreds of devices were stressed in the off-state with various drain voltages from 75 V to 400 V while irradiated with a high-intensity neutron beam. Observing a statistically significant number of neutron-induced destructive single-event-effects (DSEEs) enabled an accurate extrapolation of terrestrial field failure rates. Nuclear event and electronic simulations were performed to model the effect of terrestrial neutron secondary ion-induced gate dielectric breakdown. Combined with the TCAD simulation results, we believe that heavy-ion-induced SEGR and neutron-induced SEGR share common physics mechanisms behind the failures. Overall, experimental data and simulation results provide evidence supporting the idea that both radiation-induced SBD and HBD are associated with defect-related conduction paths formed across the dielectric, in response to radiation-induced charge injection. A percolation theory-based dielectric degradation model is proposed, which explains the dielectric breakdown behaviors observed in heavy-ion irradiation experiments

Analysis of GaN HEMTs Switching Transients Using Compact Model

The methodology to model GaN power HEMT switching transients at the circuit level is presented in this paper. A compact model to predict devices’ pulse switching characteristics and current collapse reliability issue has been developed. Parasitic RC subcircuits and a standard double-pulse switching tester to model intrinsic parasitic effects and to analyze power dissipation of GaN power HEMT are proposed and presented. Switching transient including gate-lag and drain-lag is predicted for ideal (without trap) and nonideal (with trap) devices. The results are validated by and compared to 2-D finite-element TCAD simulations. The developed methodology and compact model can successfully predict the dynamic behaviour of single and multiple power GaN HEMTs used for power electronics design

Characterization and Modeling of the Threshold Voltage Instability in p-Gate GaN HEMTs

The p-gate GaN HEMT is a modern power semiconductor transistor capable of overcoming the switching speed limitation of conventional Silicon-based technologies. However, the GaN HEMT is a fairly new technology that still suffers undesired effects that affect its operation. Nowadays, the most prominent effects are the shift and instability of the threshold voltage Vth, caused by capacitive coupling into the gate stack as well as trapping, accumulation, and depletion of carriers. In this study, an experimental characterization of the Vth behavior is executed and subsequently used to develop a physically-based compact model. For this purpose, a custom setup is developed capable of high-resolution transient measurements for pulse lengths ranging from 100 ns up to 100 s. Utilizing the setup, commercially available state-of-the-art p-gate GaN HEMTs are investigated, showing a Vth shift and instability that appears relevant up to the nominal operation. The experimental results show that the drain-source voltage VDS yields a Vth shift, which, when applied for long durations (e.g., during off-state), leads to an additional Vth instability. The gate-source voltage VGS also yields significant Vth instabilities, which correlate with the VDS-induced effects. Furthermore, the driving conditions causing an impact on Vth appear to also correlate with the devices’ short-circuit capability and degradation. However, no available models cover the Vth behavior, which is necessary to predict their impact and reliability concerns. Consequently, a compact model is developed based on the surface potential for the drain path, extended by the conduction mechanisms covering the gate path. Finally, the Vth shift is modeled based on capacitive coupling into the gate, while for the Vth instabilities, a possible implementation is exemplified for the impact of VDS

Temperature Dependent Analytical Modeling, Simulation and Characterizations of HEMTs in Gallium Nitride Process

Research is being conducted for a high-performance building block for high frequency and high temperature applications that combine lower costs with improved performance and manufacturability. Researchers have focused their attention on new semiconductor materials for use in device technology to address system improvements. Of the contenders, silicon carbide (SiC), gallium nitride (GaN), and diamond are emerging as the front-runners. GaN-based electronic devices, AlGaN/GaN heterojunction field effect transistors (HFETs), are the leading candidates for achieving ultra-high frequency and high-power amplifiers. Recent advances in device and amplifier performance support this claim. GaN is comparable to the other prominent material options for high-performance devices. The dissertation presents the work on analytical modeling and simulation of GaN high power HEMT and MOS gate HEMT, model verification with test data and device characterization at elevated temperatures. The model takes into account the carrier mobility, the doping densities, the saturation velocity, and the thickness of different layers. Considering the GaN material processing limitations and feedback from the simulation results, an application specific AlGaN/GaN RF power HEMT structure has been proposed. The doping concentrations and the thickness of various layers are selected to provide adequate channel charge density for the proposed devices. A good agreement between the analytical model, and the experimental data is demonstrated. The proposed temperature model can operate at higher voltages and shows stable operation of the devices at higher temperatures. The investigated temperature range is from 1000K to 6000K. The temperature models include the effect of temperature variation on the threshold voltage, carrier mobility, bandgap and saturation velocity. The calculated values of the critical parameters suggest that the proposed device can operate in the GHz range for temperature up to 6000K, which indicates that the device could survive in extreme environments. The models developed in this research will not only help the wide bandgap device researchers in the device behavioral study but will also provide valuable information for circuit designers

Modeling of gallium nitride transistors for high power and high temperature applications

Wide bandgap (WBG) semiconductors such as GaN and SiC are emerging as promising alternatives to Si for new generation of high efficiency power devices. GaN has attracted a lot of attention recently because of its superior material properties leading to potential realization of power transistors for high power, high frequency, and high temperature applications. In order to utilize the full potential of GaN-based power transistors, proper device modeling is essential to verify its operation and improve the design efficiency. In this view, this research work presents modeling and characterization of GaN transistors for high power and high temperature applications. The objective of this research work includes three key areas of GaN device modeling such as physics-based analytical modeling, device simulation with numerical simulator and electrothermal SPICE model for circuit simulation. The analytical model presented in this dissertation enables understanding of the fundamental physics of this newly emerged GaN device technology to improve the operation of existing device structures and to optimize the device configuration in the future. The numerical device simulation allows to verify the analytical model and study the impact of different device parameters. An empirical SPICE model for standard circuit simulator has been developed and presented in the dissertation which allows simulation of power electronic circuits employing GaN power devices. The empirical model provides a good approximation of the device behavior and creates a link between the physics-based analytical model and the actual device testing data. Furthermore, it includes an electrothermal model which can predict the device behavior at elevated temperatures as required for high temperature applications.Includes bibliographical reference