High‐temperature electrical performances and physics‐based analysis of p‐GaN HEMT device

Li, Sheng; Liu, Siyang; Tian, Yu‐Ping; Zhang, Chi; Wei, Jiaxing; Tao, Xinyi; Zhang, Long; Sun, Weifeng

doi:10.1049/iet-pel.2019.0510

Cited by 10 publications

(4 citation statements)

References 19 publications

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“…The physical mechanism behind the degradation effects for pulsed and prolonged V GS bias stress on the p-GaN gate HEMT is explained in the Figure 9a,b. In view of the Schottky gate contact of the studied device, where the metal/p-GaN hetero-structure acts as Schottky junction diode and the p-GaN/AlGaN/GaN structure acts as p-i-n junction diode, and respective junction capacitances [38,39]. Under negative gate bias, the J Schottky is forward biased, with small voltage drop on it.…”

Section: Influenced Degradation Mechanism and Analyzationsmentioning

confidence: 99%

Analysis of Instability Behavior and Mechanism of E-Mode GaN Power HEMT with p-GaN Gate under Off-State Gate Bias Stress

2021

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In this study, we investigate the degradation characteristics of E-mode GaN High Electron Mobility Transistors (HEMTs) with a p-GaN gate by designed pulsed and prolonged negative gate (VGS) bias stress. Device transfer and transconductance, output, and gate-leakage characteristics were studied in detail, before and after each pulsed and prolonged negative VGS bias stress. We found that the gradual degradation of electrical parameters, such as threshold voltage (VTH) shift, on-state resistance (RDS-ON) increase, transconductance max (Gm, max) decrease, and gate leakage current (IGS-Leakage) increase, is caused by negative VGS bias stress time evolution and magnitude of stress voltage. The significance of electron trapping effects was revealed from the VTH shift or instability and other parameter degradation under different stress voltages. The degradation mechanism behind the DC characteristics could be assigned to the formation of hole deficiency at p-GaN region and trapping process at the p-GaN/AlGaN hetero-interface, which induces a change in the electric potential distribution at the gate region. The design and application of E-mode GaN with p-GaN gate power devices still need such a reliability investigation for significant credibility.

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Section: Influenced Degradation Mechanism and Analyzationsmentioning

confidence: 99%

Analysis of Instability Behavior and Mechanism of E-Mode GaN Power HEMT with p-GaN Gate under Off-State Gate Bias Stress

2021

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“…Due to the Schottky gate contact of the p-GaN gate HEMTs, the metal/p-GaN structure performs as a Schottky diode (D J1 in figure 8), the p-GaN/AlGaN/GaN structure performs as a p-i-n diode (D J2 in figure 8), and C J1 and C J2 are the junction capacitances of D J1 and D J2 , respectively [16]. At the reverse gate bias, the D J1 is forward-biased with a decreased depletion width in the p-GaN layer.…”

Section: Dominant Degradation Mechanisms and Analyzationsmentioning

confidence: 99%

“…At a high temperature, ionized holes in the p-GaN cap will also increase [16]. At the same negative V gs bias, ionized holes in the p-GaN cap can provide a more positive charge to balance the voltage drift induced by the negative gate voltage.…”

Section: Dominant Degradation Mechanisms and Analyzationsmentioning

confidence: 99%

Electrical performances degradations and physics based mechanisms under negative bias temperature instability stress for p-GaN gate high electron mobility transistors

Zhang

Liu

et al. 2020

Semicond. Sci. Technol.

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In this paper, an in-depth evaluation of the negative bias temperature instability (NBTI) in p-GaN gate high electron mobility transistors with Schottky-type gate contact has been reported in detail. The measured results reveal that the threshold voltage (V th) positively shifts by 0.35 V and the on-state drain-source resistance (R dson) increases by 24.2 mΩ within 1 h at room temperature, even under the minimum allowed operating gate-voltage condition (V gs = −10 V) in the datasheet of the commercial device. With the help of energy band theory and experimental analyses, donor-type traps are demonstrated to dominate the degradation by reducing the positive charges in the p-GaN cap. Moreover, further quantitative analysis has been performed by the conductance–frequency measurements method. Considering the risk of degradation induced by NBTI, it turns necessary for the system designers to choose a more suitable negative bias operating condition so as to extend the robustness of the entire power system.

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“…However, AlGaN/GaN heterostructure is a promising material system for high-temperature electronics. HEMTs that can operate at high temperatures are helpful in broad extent of applications [ 13 , 19 ]. Consequently, the high-temperature characteristics of the passivated AlGaN/GaN HEMTs are measured herein.…”

Section: Introductionmentioning

confidence: 99%

Large-Signal Linearity and High-Frequency Noise of Passivated AlGaN/GaN High-Electron Mobility Transistors

Lin

2020

Micromachines

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This study proposes AlGaN/GaN/silicon high-electron mobility transistors (HEMTs) grown by a metallorganic chemical vapor deposition (MOCVD) system. The large-signal linearity and high-frequency noise of HEMTs without and with different passivation layers are compared. The experimental data show that the addition of a TiO2 passivation layer to undoped AlGaN/GaN HEMT’s increases the value of the third-order intercept point (OIP3) by up to 70% at 2.4 GHz. Furthermore, the minimum noise figure (NFmin) of the HEMT with TiO2 passivation is significantly reduced.

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High‐temperature electrical performances and physics‐based analysis of p‐GaN HEMT device

Cited by 10 publications

References 19 publications

Analysis of Instability Behavior and Mechanism of E-Mode GaN Power HEMT with p-GaN Gate under Off-State Gate Bias Stress

Analysis of Instability Behavior and Mechanism of E-Mode GaN Power HEMT with p-GaN Gate under Off-State Gate Bias Stress

Electrical performances degradations and physics based mechanisms under negative bias temperature instability stress for p-GaN gate high electron mobility transistors

Large-Signal Linearity and High-Frequency Noise of Passivated AlGaN/GaN High-Electron Mobility Transistors

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