Investigation on Traps Dynamics & Negative Bias Stress in D-Mode GaN-on-Si Power MIS HEMTs Under High-Temperature

IF 2.5 3区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Device and Materials Reliability Pub Date : 2024-07-10 DOI:10.1109/TDMR.2024.3426526

Shivendra K. Rathaur;Le Trung Hieu;Tsung-Ying Yang;Shang Hua Tsai;Wen Yu Lin;Abhisek Dixit;Edward Yi Chang

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Abstract

This experimental study investigates the traps dynamics and threshold voltage (VTH) shift mechanism under negative bias temperature stress for the GaN-on-Si Power MIS HEMTs on field plate design structure. Based on the experimental analysis, two distinct activation energies (Ea) have been identified under the specific reverse bias conditions of VGS= -30 V and VDS=0 V in a wide temperature range. Reverse bias stress experiments (up to 10 ks) show a positive VTH shift of ~1.6 V at room temperature due to the inversion of the charges at the interface between the insulator and AlGaN layer, resulting in net negative charge near the gate region. Subsequently, there is a decrease in VTH shift till

$125~^{\circ }$

C because of the de-trapping of the inversion charges. This phenomenon shows a strong correlation with a thermally activated activation energy of (E

${_{\text {a}}}~\approx ~0.23$

eV). Further, the shift in

${\mathrm { V}}_{\mathrm { TH}}$

turns negative when the temperature is raised to

$175~^{\circ }$

C, indicating the accumulation of electrons in the channel layer with activation energy (E

${_{\text {a}}}~\approx ~0.78$

eV) attributed to the activation of nitrogen interstitials from the GaN buffer layer. Additionally, the recovery (up to 10 ks) behavior demonstrates the exponential-linear settlement of the traps to recover the

${\mathrm { V}}_{\mathrm { TH}}$

shift. Moreover, nitrogen interstitials take more time to suppress the threshold voltage instabilities. These findings explain the

${\mathrm { V}}_{\mathrm { TH}}$

shift mechanisms in GaN-on-Si Power MIS HEMTs under NBTI.

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高温条件下 D 模式硅基氮化镓功率 MIS HEMT 陷阱动力学和负偏压应力研究

本实验研究调查了采用场板设计结构的硅基氮化镓功率 MIS HEMT 在负偏压温度应力下的阱动力学和阈值电压（VTH）移动机制。根据实验分析，在 VGS= -30 V 和 VDS=0 V 的特定反向偏压条件下，在较宽的温度范围内确定了两种不同的活化能 (Ea)。反向偏压应力实验（高达 10 ks）显示，在室温下，由于绝缘体和 AlGaN 层界面上的电荷发生反转，导致栅极区附近出现净负电荷，VTH 发生了 ~1.6 V 的正向移动。随后，由于反转电荷的去俘获作用，VTH 位移在 125~^{\circ }$ C 时会减小。这一现象与热激活的活化能（E ${_{\text {a}}~approx ~0.23$ eV）密切相关。）此外，当温度升高到 175~^{\circ }$ C 时，${mathrm { V}}_{\mathrm { TH}}$ 的偏移变为负值，这表明电子在沟道层中积累，其活化能（E ${_{\text {a}}~approx ~0.78$ eV）归因于氮间杂物从氮化镓缓冲层中的活化。此外，恢复（高达 10 ks）行为表明，阱在恢复 ${\mathrm { V}}_{\mathrm { TH}}$ 漂移时呈指数线性沉降。此外，氮间质需要更多的时间来抑制阈值电压的不稳定性。这些发现解释了氮化镓硅功率 MIS HEMT 在 NBTI 下的 ${mathrm { V}}_{\mathrm { TH}}$ 漂移机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Device and Materials Reliability 工程技术-工程：电子与电气

CiteScore

4.80

自引率

5.00%

发文量

审稿时长

6-12 weeks

期刊介绍： The scope of the publication includes, but is not limited to Reliability of: Devices, Materials, Processes, Interfaces, Integrated Microsystems (including MEMS & Sensors), Transistors, Technology (CMOS, BiCMOS, etc.), Integrated Circuits (IC, SSI, MSI, LSI, ULSI, ELSI, etc.), Thin Film Transistor Applications. The measurement and understanding of the reliability of such entities at each phase, from the concept stage through research and development and into manufacturing scale-up, provides the overall database on the reliability of the devices, materials, processes, package and other necessities for the successful introduction of a product to market. This reliability database is the foundation for a quality product, which meets customer expectation. A product so developed has high reliability. High quality will be achieved because product weaknesses will have been found (root cause analysis) and designed out of the final product. This process of ever increasing reliability and quality will result in a superior product. In the end, reliability and quality are not one thing; but in a sense everything, which can be or has to be done to guarantee that the product successfully performs in the field under customer conditions. Our goal is to capture these advances. An additional objective is to focus cross fertilized communication in the state of the art of reliability of electronic materials and devices and provide fundamental understanding of basic phenomena that affect reliability. In addition, the publication is a forum for interdisciplinary studies on reliability. An overall goal is to provide leading edge/state of the art information, which is critically relevant to the creation of reliable products.

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