Reliability in GaN-based devices for power applications

2018 IEEE Third Ecuador Technical Chapters Meeting (ETCM) Pub Date : 2018-10-01 DOI:10.1109/ETCM.2018.8580263

E. Acurio, L. Trojman, F. Crupi, F. Iucolano, N. Ronchi, B. de Jaeger, B. Bakeroot, S. Decoutere

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引用次数: 2

Abstract

This paper analyzes two important reliability issues in AlGaN/GaN devices: positive bias temperature instability (PBTI) and time-dependent dielectric breakdown (TDDB). The summarized results of our previous PBTI studies in MOS-HEMTs show that the threshold voltage degradation in devices with SiO2 as gate dielectric is characterized by a universal decreasing behavior of the trapping rate parameter and is ascribed to charge trapping in the SiO2 and at the SiO2/GaN interface. On the contrary, the degradation observed in Al2O3- and AlN/Al2O3-gate stacks is mainly attributed to charge capture in the pre-existing dielectric traps with a negligible interface state generation. Additionally, the insertion of a thin AlN layer impacts on the device reliability because larger trap density, faster charge trapping, wider trap energy distribution and slower charge release are observed compared with devices without this layer. The dielectric importance of GaN-based devices has been also investigated in Schottky Barrier Diodes (SBDs) with a gated edge termination (GET). Our recent TDDB results indicate a narrower Weibull distribution, and a longer time to failure in devices with a double GET layer structure and with a thick passivation layer (2 GET-THICK) than in single GET devices with a thin passivation (1 GET-THIN). Therefore, the former structure is more suitable for high-power and high-temperature applications.

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电源应用中基于氮化镓器件的可靠性

本文分析了AlGaN/GaN器件的两个重要可靠性问题:正偏置温度不稳定性(PBTI)和时变介电击穿(TDDB)。我们之前在mos - hemt中进行的PBTI研究结果表明，以SiO2为栅极介质的器件的阈值电压退化具有捕获速率参数普遍下降的特征，并归因于SiO2和SiO2/GaN界面处的电荷捕获。相反，在Al2O3-和AlN/Al2O3栅极堆中观察到的退化主要归因于预先存在的介电阱中的电荷捕获，而界面态的产生可以忽略不计。此外，薄AlN层的插入会影响器件的可靠性，因为与没有该层的器件相比，可以观察到更大的陷阱密度、更快的电荷捕获、更宽的陷阱能量分布和更慢的电荷释放。在具有门控边缘终端(GET)的肖特基势垒二极管(sdd)中，也研究了gan基器件的介电重要性。我们最近的TDDB结果表明，与具有薄钝化层(1 GET- thin)的单GET器件相比，具有双GET层结构和厚钝化层(2 GET- thick)的器件具有更窄的威布尔分布和更长的失效时间。因此，前者结构更适合大功率和高温应用。

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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2018 IEEE Third Ecuador Technical Chapters Meeting (ETCM)

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