Your search keyword '"LYU Gang"' showing total 7 results

1. Short-Circuit Characteristics and High-Current Induced Oscillations in a 1200-V/80-mΩ Normally-Off SiC/GaN Cascode Device.

Author

Lyu, Gang, Sun, Jiahui, Wang, Yuru, and Chen, Kevin J.

Subjects

*MODULATION-doped field-effect transistors, *FIELD-effect transistors, *GALLIUM nitride, *CURRENT fluctuations, *STRAY currents

Abstract

A normally-off SiC-JFET/GaN-HEMT cascode device is recently proposed, featuring a cascode configuration that incorporates a high-voltage (HV, e.g., 1200 V) silicon-carbide (SiC) junction field effect transistor (JFET) delivering the HV blocking capability and a low-voltage (LV) enhanced-mode (E-mode) gallium-nitride (GaN) high electron mobility transistor (HEMT) providing the normally-off gate control. This all-wide-bandgap device exhibits superior thermal stability and high switching speed compared to its counterparts, e.g., the SiC/Si cascode device. In this article, we study short-circuit (SC) characteristics of a 1200-V/80-mΩ SiC/GaN cascode device by considering the interactions between the SiC and GaN devices. The single-event SC withstand time (SCWT) of the demonstrated SiC/GaN cascode device is tested to be ∼3 μs under a dc-bus voltage (Vdc) of 600 V when the turn-on gate voltage (VG-on) is set to 5 V. The SC failure occurs due to the formation of hot spots induced by thermal-runaway leakage currents inside the SiC JFET. The SCWT of the cascode device could be improved by applying a moderate VG-on (e.g., SCWT = ∼6.5 μs at VG-on = 3.5 V under v dc = 600 V) without affecting the on-state resistance (r on). However, it is identified that current oscillations tend to be triggered during the SC period when VG-on is too low (e.g., lower than 3 V). The oscillation behavior is attributed to the energy stored in the interconnection parts between the SiC and GaN devices. The harmful oscillations could be suppressed by applying higher VG-on, which drives the SiC JFET into low-transconductance mode by modulating the drain-to-source voltage (VDS-G) of the LV GaN HEMT. [ABSTRACT FROM AUTHOR]

Published

2022

2. 650-V Normally-OFF GaN/SiC Cascode Device for Power Switching Applications.

Author

Zhong, Kailun, Wang, Yuru, Lyu, Gang, Wei, Jin, Sun, Jiahui, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, GALLIUM nitride, THRESHOLD voltage

Abstract

A 650-V/84-mΩ normally-off GaN/SiC cascode device is demonstrated with systematic static and dynamic characterizations. The cascode device features a low-voltage enhancement-mode (E-mode) gallium nitride (GaN) high electron mobility transistor (HEMT) to enable normally-off gate control, and a 650-V normally-on silicon carbide (SiC) JFET provides the high-voltage blocking capability. The GaN/SiC cascode device exhibits many application-desired behaviors, including reverse conduction capability, avalanche breakdown capability, thermally stable threshold voltage, low input/output capacitances, no dynamic RON degradation, and negligible dynamic VTH shift. In addition, a customized double-pulse test board is built to evaluate the switching performance of this cascode device and other 650-V SiC-based power devices. This cascode device adopting low-voltage GaN HEMT has low QG×RON and exhibits excellent switching performance. The switching losses (EON and EOFF) are much smaller than that of the 650-V Si/SiC cascode device and comparable to that of the state-of-the-art 650-V SiC MOSFETs. [ABSTRACT FROM AUTHOR]

Published

2022

3. Short-Circuit Failure Mechanisms of 650-V GaN/SiC Cascode Devices in Comparison With SiC MOSFETs.

Author

Sun, Jiahui, Zhong, Kailun, Zheng, Zheyang, Lyu, Gang, and Chen, Kevin J.

Subjects

METAL oxide semiconductor field-effect transistors, FIELD-effect transistors, JUNCTION transistors, MODULATION-doped field-effect transistors, GALLIUM nitride, FAILURE mode & effects analysis

Abstract

Although the gallium nitride (GaN) high-electron-mobility transistor/silicon carbide (SiC) junction field-effect transistor (JFET) cascode device exhibits certain performance advantages over the SiC metal–oxide–semiconductor field-effect transistor (MOSFET), its robustness in harsh operating conditions is unknown. In this work, the short-circuit (SC) robustness of 650-V GaN/SiC cascode devices is characterized, analyzed, and compared with that of several mainstream SiC MOSFETs. GaN/SiC cascode devices exhibit competitive SC capability. Different failure modes are observed: thermal runaway in the SiC JFET of the cascode device and gate-to-source breakdown in the SiC MOSFET. The difference is associated with the configuration of the dielectric above SiC in the JFET and the source pad layout. According to the waveforms in SC events, failure spots, and thermal simulation results, a thermal runaway in the SiC JFET is attributed to the positive feedback between the drain leakage current and the junction temperature in the local area (hotspot) without the source pad on the top. The SC withstand time of the cascode device can be extended by reduction of the active area without the source pad. [ABSTRACT FROM AUTHOR]

Published

2022

4. Impact of Drain Leakage Current on Short Circuit Behavior of GaN/SiC Cascode Devices.

Author

Sun, Jiahui, Zheng, Zheyang, Zhong, Kailun, Lyu, Gang, and Chen, Kevin J.

Subjects

STRAY currents, SHORT circuits, GALLIUM nitride, FAILURE analysis, MODULATION-doped field-effect transistors, THRESHOLD voltage, SUPERCONTINUUM generation

Abstract

The short circuit (SC) behavior of a newly developed GaN-HEMT/SiC-JFET cascode device is investigated in this work. The reverse leakage current through the drain-side PN junction (IR) of the SiC JFET under SC conditions is measured simultaneously during the SC event. IR of the SiC JFET increases to 6.4 A at the end of a 5-μs nondestructive SC pulse. The increase of IR during the SC pulse induces a turning point in the SC current waveform and a dramatic negative threshold voltage shift (>30 V) in the SiC JEFT, resulting in high transient drain-to-source voltage in the GaN HEMT. The underlying mechanism is associated with the increase of local potential in the P-type layer of the SiC JFET with inevitable spread resistance (RSPD). It is suggested that reducing RSPD can improve SC capability and high IR should be considered in SC failure mechanism analysis and the design of external gate resistance of the SiC JFET. [ABSTRACT FROM AUTHOR]

Published

2021

5. Characterization of Static and Dynamic Behavior of 1200 V Normally off GaN/SiC Cascode Devices.

Author

Wang, Yuru, Lyu, Gang, Wei, Jin, Zheng, Zheyang, He, Jiabei, Lei, Jiacheng, and Chen, Kevin J.

Subjects

*FIELD-effect transistors, *SILICON carbide, *MODULATION-doped field-effect transistors, *BREAKDOWN voltage, *THRESHOLD voltage

Abstract

Systematic characterizations of a cascode device with a low-voltage enhance-mode (E-mode) p-GaN gate high-electron mobility transistor as the control device and a high-voltage (HV) depletion-mode (D-mode) silicon carbide junction field effect transistor (JFET) as the voltage blocking device are presented in this article. The demonstrated device with a breakdown voltage rating of 1200 V and a static on-resistance (RON) of 100 mΩ features small device capacitances with fast switching speed, avalanche breakdown capability, thermally stable threshold voltage (VTH), and no dynamic RON degradation. To identify its safe operation in the off-state with a high drain bias, the off-state middle point voltage (VM) between the E-mode device drain and D-mode device source is investigated. A relatively low off-state VM is achieved under both static and dynamic modes. In addition to the device-level characterization, a custom-designed double-pulse test circuit is built to evaluate the transient switching performance of the cascode device. Optimal gate drive conditions are proposed to 1) overcome the drain bias induced positive dynamic VTH shift; and 2) suppress the increased dynamic off-state leakage current (IOFF) induced by on-state hole injection. Under 800 V/16 A testing conditions, high switching speed with the drain voltage peak slew rates of 72 V/ns during turn-on and 121 V/ns during turn-off is achieved. [ABSTRACT FROM AUTHOR]

Published

2020

6. A Normally-off Copackaged SiC-JFET/GaN-HEMT Cascode Device for High-Voltage and High-Frequency Applications.

Author

Lyu, Gang, Wang, Yuru, Wei, Jin, Zheng, Zheyang, Sun, Jiahui, Zhang, Long, and Chen, Kevin J.

Subjects

*MODULATION-doped field-effect transistors, *GALLIUM nitride, *POWER transistors, *HYBRID power, *SILICON carbide, *THRESHOLD voltage

Abstract

A 1200-V/100-mΩ silicon carbide (SiC) junction field-effect-transistor (JFET)/ gallium nitride (GaN) high-electron-mobility-transistor (HEMT) hybrid power switch is demonstrated, which features a flip-chip copackaged cascode configuration incorporating a vertical SiC JFET and a lateral GaN-HEMT. The high-voltage SiC-JFET provides the high-voltage blocking capability while the low-voltage GaN-HEMT enables the normally-off gate control with superior switching characteristics. Compared to conventional SiC-JFET/Si-mosfet cascode devices, the SiC-JFET/GaN-HEMT cascode device exhibits fast switching speed, which has been validated by systematic characterizations including static/dynamic device-level measurements and board-level hard-switching tests. Meanwhile, the device is free from several notorious issues of high-voltage GaN power transistors such as dynamic on-state resistance degradation and threshold voltage shift. Such a wide-bandgap semiconductor-based hybrid switch is suitable to be deployed in high-power and high-efficiency power conversion systems. [ABSTRACT FROM AUTHOR]

Published

2020

7. Mechanism and Novel Structure for di/dt Controllability in U-Shaped Channel Silicon-on-Insulator Lateral IGBTs.

Author

Zhang, Long, Zhu, Jing, Cao, Shilin, Ma, Jie, Li, Ankang, Wei, Jin, Lyu, Gang, Li, Shaohong, Li, Sheng, Wei, Jiaxing, Wu, Wangran, Sun, Weifeng, and Chen, Kevin J.

Subjects

INSULATED gate bipolar transistors, CONTROLLABILITY in systems engineering, ELECTRIC potential, VOLTAGE regulators

Abstract

A planar gate U-shaped (PGU) channel silicon-on-insulator (SOI) lateral insulated gate bipolar transistor (LIGBT) featuring divided gates (G1 and G2) is proposed, which aims to suppress the gate voltage (VG) overshoot and improve the di/dt controllability. In the conventional PGU structure, the hole accumulating and the electric potential rising in the JFET region leads to a displacement current to overcharge the gate during the turn-on transient. Two gate connection modes (Mode A and B) for the proposed PGU structure are discussed. Mode A with a grounded G2 can effectively enhance the VG stability, however, degenerating the on-state voltage (VON). Mode B shields the displacement current by a pre-charged G2. G2 is driven with a separate gate resistor to the main gate G1, which results in an improved di/dt controllability without deteriorating VON. When adjusted for the same turn-on loss of 5.28mJ/cm2, the di/dt of the proposed PGU structure with mode B is 74% lower than that of the conventional PGU structure. [ABSTRACT FROM AUTHOR]

Published

2019