Your search keyword '"Hua, Mengyuan"' showing total 18 results

1. Gate Leakage and Reliability of GaN -Channel FET With SiNₓ/GaON Staggered Gate Stack.

Author

Zhang, Li, Zheng, Zheyang, Song, Wenjie, Chen, Tao, Feng, Sirui, Chen, Junting, Hua, Mengyuan, and Chen, Kevin J.

Subjects

GALLIUM nitride, LEAKAGE, FIELD-effect transistors, POTASSIUM channels, PLASMA temperature, LOGIC circuits

Abstract

${p}$ -channel GaN field-effect transistors (FETs) with a SiNx/GaON gate stack have been demonstrated with enhanced stability within a wide range of voltage bias and temperature. In this letter, the gate leakage characteristics and reliability of this unconventional staggered gate stack are investigated. At relatively low gate voltages, the gate current is suppressed owing to the buried-channel structure and the presence of GaON that presents an effective hole barrier. With more negative gate biases, the gate leakage was found to be dominated by the transport of holes that spillover from the ${p}$ -channel through the SiNx via Poole-Frenkel emission. Based on this gate leakage mechanism at large gate bias, $\sqrt {{\mathrm {E}}} $ model was used for gate lifetime prediction. The maximum applicable ON-state gate voltage of −7.3 V is obtained for a 10-year lifetime with a 1% gate failure rate. [ABSTRACT FROM AUTHOR]

Published

2022

2. Negative Gate Bias Induced Dynamic ON-Resistance Degradation in Schottky-Type p -Gan Gate HEMTs.

Author

Jiang, Zuoheng, Hua, Mengyuan, Huang, Xinran, Li, Lingling, Wang, Chengcai, Chen, Junting, and Chen, Kevin J.

Subjects

*MODULATION-doped field-effect transistors, *IMPACT ionization, *LOGIC circuits

Abstract

In this article, the impacts of the off-state gate bias (VGS,OFF) on dynamic on-resistance (RON) are systematically investigated in commercial Schottky-type p-GaN Gate high-electron-mobility transistors. Double-pulse tester and pulsed I–V system are adopted to evaluate the dynamic RON with various off-state gate and drain bias (VDS,OFF) under hard- and soft-switching conditions. More negative VGS,OFF can aggravate the dynamic RON degradation under both soft- and hard-switching, especially when switching with a high VDS,OFF. The impacts of VGS,OFF on switching transients and off-state stress are investigated separately to reveal the underlying mechanisms, which are found to be associated with the generation and movements of holes. The off-state gate bias of the voltage-driving scheme needs to be carefully considered according to the identified mechanisms in terms of dynamic on-resistance degradation. [ABSTRACT FROM AUTHOR]

Published

2022

3. Decoupling of Forward and Reverse Turn-on Threshold Voltages in Schottky-Type p-GaN Gate HEMTs.

Author

Chen, Junting, Hua, Mengyuan, Wang, Chengcai, Liu, Ling, Li, Lingling, Wei, Jin, Zhang, Li, Zheng, Zheyang, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, THRESHOLD voltage, WIDE gap semiconductors, HIGH voltages, ALUMINUM gallium nitride

Abstract

In a ${p}$ -channel field-effect-transistor (${p}$ -FET) bridge HEMT device recently realized on a commercial ${p}$ -GaN/AlGaN/GaN-on-Si power HEMT epi-wafer, it is revealed that the device’s reverse-conduction turn-on voltage (${V}_{\text {RT}}$) can be effectively decoupled from the forward threshold voltage (${V}_{\text {TH}}$) of Schottky-type ${p}$ -GaN gate HEMTs. Unlike the conventional Schottky-type ${p}$ -GaN gate HEMTs, of which ${V}_{\text {RT}}$ is closely linked to ${V}_{\text {TH}}$ , the ${p}$ -FET-bridge HEMT enables separate designs of ${V}_{\text {RT}}$ and $V_{\text {TH}}$ so that low-loss reverse conduction and high threshold voltage can be simultaneously realized. In addition, ${V}_{\text {RT}}$ can be further reduced by engineering the AlGaN barrier layer, which will also benefit a lower channel sheet resistance without lowering ${V}_{\text {TH}}$. [ABSTRACT FROM AUTHOR]

Published

2021

4. Gate Current Transport in Enhancement-Mode p-n Junction/AlGaN/GaN (PNJ) HEMT.

Author

Hua, Mengyuan, Wang, Chengcai, Chen, Junting, Zhao, Junlei, Yang, Song, Zhang, Li, Zheng, Zheyang, Wei, Jin, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, GALLIUM nitride

Abstract

In this work, we study the gate leakage mechanisms of E-mode p-n junction/AlGaN/GaN (PNJ) high electron mobility transistors (HEMTs), which have been shown to deliver low gate leakage and wide safe operating gate-bias range. The intrinsic gate leakage through the PNJ-gate was found to be limited by the transport of holes through the p-GaN layer, which occurs via Poole-Frenkel emission and phonon-assisted tunneling in low and high gate bias region, respectively. In addition, lateral leakage current and the role of variable hopping process (VRH) are also discussed. Gate leakage current models based on the revealed mechanisms can quantitatively reproduce the gate-leakage behavior in the entire relevant range of gate biases and temperatures. [ABSTRACT FROM AUTHOR]

Published

2021

5. E-Mode p-n Junction/AlGaN/GaN (PNJ) HEMTs.

Author

Wang, Chengcai, Hua, Mengyuan, Chen, Junting, Yang, Song, Zheng, Zheyang, Wei, Jin, Zhang, Li, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, BREAKDOWN voltage, THRESHOLD voltage

Abstract

In this work, we demonstrate a GaN-based $\textit {p-n}$ junction gate (PNJ) HEMT featuring an ${n}$ -GaN/ ${p}$ -GaN/AlGaN/GaN gate stack. Compared to the more conventional ${p}$ -GaN gate HEMT with a Schottky junction between the gate metal and ${p}$ -GaN layer, the $\textit {p-n}$ junction can withstand higher reverse bias at the same peak electric-field as the depletion region extends to both the ${n}$ -side and ${p}$ -side, while exhibiting lower leakage current. The PNJ-HEMT shows a positive threshold voltage (${V}_{\text {TH}}$) of 1.78 V, a small gate leakage $(\sim 10^{-3}$ mA/mm @ ${V}_{\text {GS}} = {10}\,\, \text {V}$). In particular, a large forward gate breakdown voltage of 19.35 V at 25 °C and 19.70 V at 200 °C was achieved with the PNJ-gate HEMT. [ABSTRACT FROM AUTHOR]

Published

2020

6. Investigation of Dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ Under Switching Operation in Schottky-Type p-GaN Gate HEMTs.

Author

Wang, Yuru, Wei, Jin, Yang, Song, Lei, Jiacheng, Hua, Mengyuan, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, GATES, ELECTRON traps, HIGH temperatures

Abstract

In this paper, systematic characterization and the corresponding suppression strategies of dynamic OFF-state leakage current (${I}_{ \mathrm{\scriptscriptstyle OFF}}$) in Schottky-type p-GaN gate high-electron-mobility transistors (HEMTs) are presented based on fast pulsed ${I}$ – ${V}$ measurement and consecutive switching measurement. It is found that the high ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ under dynamic pulse mode without hole injection is a result of the reduced voltage blocking capabilities (both lateral and vertical) with weaker trapping effect in the buffer, and the dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ induced by ON-state hole injection is caused by further increased lateral conductivity through the buffer from source to drain. The corresponding behaviors under continuous waveforms with different switching conditions are analyzed to identify effective approaches for the suppression of dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ in practical switching operations. A higher temperature is shown to be beneficial to the reduction of the dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ induced by ON-state hole injection. To completely eliminate the dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ caused by ON-state hole injection and minimize the OFF-state power consumption in practical power switching applications, a sufficiently large negative OFF-state gate bias (e.g., ${V}_{\text {GS}, \mathrm{\scriptscriptstyle OFF}}\le -{3}$ V) is recommended in the gate driver turn-off voltage design for the Schottky-type p-GaN gate HEMTs. [ABSTRACT FROM AUTHOR]

Published

2019

7. Reverse-Conducting Normally-OFF Double-Channel AlGaN/GaN Power Transistor With Interdigital Built-in Schottky Barrier Diode.

Author

Lei, Jiacheng, Wei, Jin, Tang, Gaofei, Qian, Qingkai, Zhang, Zhaofu, Hua, Mengyuan, Zheng, Zheyang, and Chen, Kevin J.

Subjects

SCHOTTKY barrier diodes, POWER transistors, BREAKDOWN voltage, METAL oxide semiconductor field, WIDE gap semiconductors, THRESHOLD voltage, VARISTORS

Abstract

Low-loss reverse-conducting normally- OFF double-channel AlGaN/GaN power transistor with the built-in Schottky barrier diode (SBD) has been systematically studied. This device features the MOS-gate section and SBD-anode section paralleled to an interdigital layout along the gate width direction. A common access region that conducts current at both forward and reverse ON-states is employed, which is beneficial to reduce the conduction loss. With a MOS-HEMT/SBD finger width of ${4}~\mu \text{m}/2~\mu \text{m}$ and a total width ratio of 2:1, the device exhibits a threshold voltage of +0.8 V at a drain current of ${10}~\mu \text{A}$ /mm and a low forward ON-resistance of $12.1~\Omega \cdot \text {mm}$. The Schottky metal contacts 2-DEG directly, which results in a low reverse turn-on voltage of −0.6 V (at −1 mA/mm) and low reverse ON-state voltage of −1.7 V (at −50 mA/mm). A leakage suppression MOS field plate (FP) is applied to shield the Schottky contact from the strong electric field, leading to a low OFF-state leakage current of 14 nA/mm at +100-V drain bias and a high breakdown voltage (BV) of +698 V. The finger width and the number of fingers should be optimized. A narrow finger width benefits the current sharing at the access region, while the increasing number of fingers introduces more Schottky depletion regions along the gate width direction that degrade ${R}_{ \mathrm{\scriptscriptstyle ON}}$. [ABSTRACT FROM AUTHOR]

Published

2019

8. Charge Storage Mechanism of Drain Induced Dynamic Threshold Voltage Shift in ${p}$ -GaN Gate HEMTs.

Author

Wei, Jin, Xie, Ruiliang, Xu, Han, Wang, Hanxing, Wang, Yuru, Hua, Mengyuan, Zhong, Kailun, Tang, Gaofei, He, Jiabei, Zhang, Meng, and Chen, Kevin J.

Subjects

THRESHOLD voltage, ELECTRIC potential, GATES, STORAGE, ELECTRIC capacity, LOGIC circuits

Abstract

The drain induced dynamic threshold voltage (${V}_{\textrm {th}}$) shift of a ${p}$ -GaN gate HEMT with a Schottky gate contact is investigated, and the underlying mechanisms are explained with a charge storage model. When the device experiences a high drain bias ${V}_{\textrm {DSQ}}$ , the gate-to-drain capacitance (${C}_{\textrm {GD}}$) is charged to ${Q}_{\textrm {GD}}$ (${V}_{\textrm {DSQ}}$). As the drain voltage drops to ${V}_{\textrm {DSM}}$ where ${V}_{\textrm {th}}$ is measured, ${C}_{\textrm {GD}}$ is expected to be discharged to ${Q}_{\textrm {GD}}$ (${V}_{\textrm {DSM}}$). However, the metal/ ${p}$ -GaN Schottky junction could block the discharging current, resulting in storage of negative charges in the ${p}$ -GaN layer. For the device to turn on, additional gate voltage is required to counteract the stored negative charges, resulting in a positive shift of ${V}_{\textrm {th}}$. The dynamic ${V}_{\textrm {th}}$ shift is an intrinsic and predictable characteristic of the ${p}$ -GaN gate HEMT which is linearly correlated with $\Delta \!{Q}_{\textrm {GD}}={Q}_{\textrm {GD}}$ (${V}_{\textrm {DSQ}}$) $- {Q}_{\textrm {GD}}$ (${V}_{\textrm {DSM}}$). The ${V}_{\textrm {th}}$ shift is dependent on ${V}_{\textrm {DSQ}}$ as well as ${V}_{\textrm {DSM}}$ , indicating that the ${V}_{\textrm {th}}$ shift is varying along the load line during a switching operation. [ABSTRACT FROM AUTHOR]

Published

2019

9. Hole-Induced Threshold Voltage Shift Under Reverse-Bias Stress in E-Mode GaN MIS-FET.

Author

Hua, Mengyuan, Wei, Jin, Bao, Qilong, Zheng, Zheyang, Zhang, Zhaofu, He, Jiabei, and Chen, Kevin Jing

Subjects

*SILICON carbide, *THRESHOLD voltage

Abstract

Under reverse-bias stress (i.e., OFF-state stress with ${V} _{\text {GS}} < {V}_{\text {TH}}$) with high drain voltage, ultraviolet (UV) illumination and larger negative gate bias are found to accelerate the positive shift in threshold voltage (${V}_{\text {TH}}$) of enhancement-mode GaN MIS-FETs with fully recessed gate. These results suggest a hole-induced degradation mechanism. In the absence of UV illumination, holes could be generated by impact ionization in the high electric-field region, which is initiated by electrons injected from the source through the buffer layer. With a larger negative gate bias, more holes will flow to the gate side and pass through the silicon nitride (SiNx) gate dielectric, as SiNx does not present any energy barrier to holes. The enhanced hole transport through the dielectric under large negative gate bias could accelerate new defects generation and therefore result in the larger positive threshold voltage shifts. [ABSTRACT FROM AUTHOR]

Published

2018

10. Dynamic OFF-State Current (Dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$) in ${p}$ -GaN Gate HEMTs With an Ohmic Gate Contact.

Author

Wang, Yuru, Hua, Mengyuan, Tang, Gaofei, Lei, Jiacheng, Zheng, Zheyang, Wei, Jin, and Chen, Kevin J.

Subjects

BUFFER layers, ENERGY bands, ELECTRICAL engineering

Abstract

The OFF-state drain leakage characteristics in 600-V p-GaN HEMTs with an ohmic gate contact are investigated under dynamic switching conditions instead of commonly used quasi-static measurement setup. It is found that fast dynamic OFF-state leakage current (dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$) is substantially higher than the slow-ramping quasi-static ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ due to the weaker trapping effect in the buffer layer. With sufficiently large positive ON-state gate bias, further increase in dynamic ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ is observed and is attributed to ON-state hole injection that leads to energy band lowering in the buffer. The underlying physical processes are explained by the dynamic behavior of the traps in the buffer layer. This letter indicates that the ${I}_{ \mathrm{\scriptscriptstyle OFF}}$ under practical switching operations is much higher than the static measurement results and should be used to evaluate dynamic OFF-state power consumption in the p-GaN HEMTs with an ohmic gate contact. [ABSTRACT FROM AUTHOR]

Published

2018

11. Performance and VTH Stability in E-Mode GaN Fully Recessed MIS-FETs and Partially Recessed MIS-HEMTs With LPCVD-SiNx/PECVD-SiNx Gate Dielectric Stack.

Author

He, Jiabei, Hua, Mengyuan, Zhang, Zhaofu, and Chen, Kevin J.

Subjects

*METAL insulator semiconductors, *FIELD-effect transistors, *DIELECTRIC devices, *ELECTRIC potential, *SEMICONDUCTORS

Abstract

In this paper, we carried out a systematic comparison between the enhancement-mode GaN-based fully recessed metal-insulator-semiconductor field-effect transistors (MIS-FETs) and partially recessed MIS-high-electron-mobility transistors (MIS-HEMTs) with the same gate dielectric stack (LPCVD-SiNx/PECVD-SiNx) that has delivered promising long-term reliability and stability. Despite a moderately larger on-resistance (${R}_{ \mathrm{ON}}$), the MIS-FETs deliver superior ${V}_{\text {TH}}$ uniformity and thermal stability. Under long-term gate bias stress, both the MIS-HEMT and MIS-FET deliver similar small positive-bias temperature instability, while the negative-bias temperature instability of the MIS-HEMT is much larger than that of MIS-FET. The MIS-FET also delivers a higher ${V}_{\text {TH}}$ stability than the MIS-HEMT under dynamic gate bias stress. It is suggested that the differences in ${V}_{\text {TH}}$ stability mainly originate from the different spatial separation between the trap states and the conducting channel, with it being larger in MIS-HEMT than in MIS-FET. [ABSTRACT FROM AUTHOR]

Published

2018

12. Reverse-Blocking Normally-OFF GaN Double-Channel MOS-HEMT With Low Reverse Leakage Current and Low ON-State Resistance.

Author

Lei, Jiacheng, Wei, Jin, Tang, Gaofei, Zhang, Zhaofu, Qian, Qingkai, Zheng, Zheyang, Hua, Mengyuan, and Chen, Kevin J.

Subjects

MODULATION-doped field-effect transistors, SCHOTTKY barrier diodes, ALUMINUM gallium nitride

Abstract

An MOS field plate-protected Schottky-drain (gated Schottky-drain) is successfully integrated on a double-channel AlGaN/GaN MOS-HEMT to provide reverse blocking capability. The leakage suppression MOS field plate is deployed on the etched upper GaN channel layer after a barrier fully recess process, leading to a low reverse OFF-state leakage current of −20 nA/mm (at −100 V). The drain metal is deployed adjacent to the MOS field plate, contacting the upper MOS-channel and lower heterojunction channel from the sidewall. A metal-2DEG Schottky contact with a low turn-ON voltage of 0.5 V is achieved. Since the lower channel (below the MOS field plate) is separated from the etched surface of upper GaN channel layer, a high-conductivity MOS-gated channel with a sheet resistance of 806 $\Omega$ /Square is obtained. The device exhibits a threshold voltage of +0.6 V (at $10~\mu \text{A}$ /mm and +1.9 V from linear extrapolation) and an ON-resistance of ~18 $\Omega {\cdot} \text {mm}$. Besides, a high forward (and reverse) breakdown voltage of 790 V (and −656 V, all at $10~\mu \text{A}$ /mm) is achieved. [ABSTRACT FROM AUTHOR]

Published

2018

13. Dependence of V\text {TH} Stability on Gate-Bias Under Reverse-Bias Stress in E-mode GaN MIS-FET.

Author

Hua, Mengyuan, Wei, Jin, Bao, Qilong, Zhang, Zhaofu, Zheng, Zheyang, and Chen, Kevin J.

Subjects

MISFET (Transistors), THRESHOLD voltage, METAL-insulator-semiconductor devices

Abstract

In this letter, we investigated the threshold voltage V\text {TH} stability under reverse-bias step-stress in the E-mode LPCVD-SiNx/PECVD-SiNx/GaN MIS-FET. Under the OFF-state reverse-bias stress with the same net gate-to-drain voltage ( V\text {GD} ), the V\text {TH} shift shows an obvious dependence on the negative gate bias. With a V\text {GS} of 0 V, the V\text {TH} shift is small and recoverable, while the V\text {TH} shifts are substantially larger with more negative gate bias ( V\text {GS}=-20 V). This larger V\text {TH} shifts caused by the negative V\text {GS} can be explained with a hole-induced degradation model. An important indication revealed by this model is that negative gate bias should be well confined in high-power switching applications of GaN E-mode MIS-FET for a stable V\text {TH} . [ABSTRACT FROM PUBLISHER]

Published

2018

14. Normally-Off LPCVD-SiNx/GaN MIS-FET With Crystalline Oxidation Interlayer.

Author

Hua, Mengyuan, Wei, Jin, Tang, Gaofei, Zhang, Zhaofu, Qian, Qingkai, Cai, Xiangbin, Wang, Ning, and Chen, Kevin J.

Subjects

MISFET (Transistors), CHEMICAL vapor deposition, OXIDATION

Abstract

Developing effective technique to protect the etched- GaN surface from the degradation in a high-temperature (i.e., at ~ 780°C) process, such as low-pressure chemical vapor deposition (LPCVD), is essential for fabricating normally-off GaN MIS-FETs with high-quality dielectric/GaN interface and highly reliable gate dielectric. In this letter, we developed an approach of obtaining such a protection layer using oxygen-plasma treatment followed by in situ annealing prior to the LPCVD-SiNx deposition. A sharp and stable crystalline oxidation interlayer (COIL) between the LPCVD-SiNx and etched-GaN was successfully formed. The LPCVD-SiNx/GaN MIS-FETs with COIL deliver normally-off operation with a VTH of 1.15 V, small on-resistance, small hysteresis, and thermally stable VTH . [ABSTRACT FROM AUTHOR]

Published

2017

15. Compatibility of AlN/SiNx Passivation With LPCVD-SiNx Gate Dielectric in GaN-Based MIS-HEMT.

Author

Hua, Mengyuan, Lu, Yunyou, Liu, Shenghou, Liu, Cheng, Chen, Kevin J., Fu, Kai, Cai, Yong, and Zhang, Baoshun

Subjects

GALLIUM nitride, METAL insulator semiconductors, MODULATION-doped field-effect transistors, ALUMINUM nitride, SILICON nitride, CHEMICAL vapor deposition, PASSIVATION, DIELECTRICS

Abstract

In this letter, we demonstrate an integrated process that illustrates the compatibility of AlN/SiNx passivation with high-performance (i.e. low leakage and high breakdown) low-pressure chemical vapor deposition (LPCVD) SiNx gate dielectric for GaN-based MIS-HEMT. It is shown that the AlN/SiNx passivation structure maintains its superior capability of suppressing the current collapse after enduring high temperature of 780 °C during the LPCVD-SiNx deposition. The AlN/SiNx passivation is shown to be significantly better than the LPCVD-SiNx passivation by delivering small dynamic $R_{{\mathrm{\scriptscriptstyle ON}}}$ degradation, especially under high drain bias switching with $V_{{\mathrm{DS}}} > 100$ V. [ABSTRACT FROM PUBLISHER]

Published

2016

16. Low On-Resistance Normally-Off GaN Double-Channel Metal–Oxide–Semiconductor High-Electron-Mobility Transistor.

Author

Wei, Jin, Liu, Shenghou, Li, Baikui, Tang, Xi, Lu, Yunyou, Liu, Cheng, Hua, Mengyuan, Zhang, Zhaofu, Tang, Gaofei, and Chen, Kevin J.

Subjects

HIGH electron mobility transistor circuits, SEMICONDUCTORS, ELECTRIC resistance, HETEROJUNCTIONS, TRANSISTORS, EXTRAPOLATION

Abstract

A low on-resistance normally-off GaN double-channel metal–oxide–semiconductor high-electron-mobility transistor (DC-MOS-HEMT) is proposed and demonstrated in this letter, which features a 1.5-nm AlN insertion layer (ISL) located 6 nm below the conventional barrier/GaN interface, forming a second channel at the interface between the AlN-ISL and the underlying GaN. With gate recess terminated at the upper channel, normally-off operation was obtained with V\mathrm {th} of +0.5 V at I\mathrm {DS}= 10 ~\mu \text{A} /mm or +1.4 V from the linear extrapolation of the transfer curve. The lower heterojunction channel is separated from the etched surface in the gate region, thereby maintaining its high field-effect mobility with a peak value of 1801 cm2/( \textV\cdot \texts ). The on-resistance is as small as 6.9 \Omega \cdot \text mm for a DC-MOS-HEMT with LG/L\mathrm {GS}/L\mathrm {GD} = 1.5/2/15~\mu \text{m} , and the maximum drain current is 836 mA/mm. A high breakdown voltage (>700 V) and a steep subthreshold swing of 72 mV/decade are also obtained. [ABSTRACT FROM AUTHOR]

Published

2015

17. Characterization of Leakage and Reliability of SiNx Gate Dielectric by Low-Pressure Chemical Vapor Deposition for GaN-based MIS-HEMTs.

Author

Hua, Mengyuan, Liu, Cheng, Yang, Shu, Liu, Shenghou, Fu, Kai, Dong, Zhihua, Cai, Yong, Zhang, Baoshun, and Chen, Kevin J.

Subjects

*CHEMICAL vapor deposition, *GALLIUM nitride, *DIELECTRICS research, *ELECTRIC leakage, *RELIABILITY in engineering

Abstract

In this paper, we systematically investigated the leakage and breakdown mechanisms of the low-pressure chemical vapor deposition (LPCVD) silicon nitride thin film deposited on AlGaN/GaN heterostructures. The LPCVD-SiNx gate dielectric exhibits low leakage and high breakdown electric field. The dominant mechanism of the leakage current through LPCVD-SiNx gate dielectric is identified to be Poole–Frenkel emission at low electric field and Fowler–Nordheim tunneling at high electric field. Both electric-field-accelerated and temperature-accelerated time-dependent dielectric breakdown of the LPCVD-SiNx gate dielectric were also investigated. [ABSTRACT FROM PUBLISHER]

Published

2015

18. GaN-Based Metal-Insulator-Semiconductor High-Electron-Mobility Transistors Using Low-Pressure Chemical Vapor Deposition SiNx as Gate Dielectric.

Author

Hua, Mengyuan, Liu, Cheng, Yang, Shu, Liu, Shenghou, Fu, Kai, Dong, Zhihua, Cai, Yong, Zhang, Baoshun, and Chen, Kevin J.

Subjects

GALLIUM nitride, METAL insulator semiconductors, MODULATION-doped field-effect transistors, CHEMICAL vapor deposition, SILICON nitride films, ELECTRIC potential

Abstract

In this letter, silicon nitride (SiNx) film deposited at 780 °C by low-pressure chemical vapor deposition (LPCVD) was employed as gate dielectric for GaN-based metal–insulator–semiconductor high-electron-mobility transistors. The LPCVD-SiNx exhibit improved gate dielectric performance than the plasma enhanced chemical vapor deposition-SiNx, including smaller forward and reverse gate leakage, and higher forward gate breakdown voltage. [ABSTRACT FROM AUTHOR]

Published

2015