失效GaN HEMT多层结构的微拉曼和扫描电镜分析

IF 1.6 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Microelectronics Reliability Pub Date : 2025-04-23 DOI:10.1016/j.microrel.2025.115754

Enza Fazio , Cettina Bottari , Santi Alessandrino , Beatrice Carbone , Salvatore Adamo , Alfio Russo , Mariangela Latino , Sabrina Conoci , Fortunato Neri , Ammar Tariq , Carmelo Corsaro

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引用次数: 0

摘要

准确诊断和理解高应力条件下氮化镓功率器件失效机制的挑战一直是一个持续存在的问题，特别是对于难以通过常规电气测量检测到的灾难性故障。本研究主要针对基于p- gan的高电子迁移率晶体管（HEMT）技术器件，在高应力条件下，分析整个器件的结构，主要是栅极源桥的结构。扫描电镜分析揭示了显著的结构损伤，包括裂纹和空洞，特别是在金属互连线和GaN缓冲层附近，而拉曼光谱则突出了纤锌矿GaN晶体结构的扭曲。通过整合光谱和形态学结果，提供了对失效机制感兴趣的GaN器件层的有用见解。这些数据有助于优化多层堆叠结构，进而提高GaN hemt的主要特性。

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Micro-Raman and SEM analyses of failed GaN HEMT multilayer architecture

The challenge of accurately diagnosing and understanding failure mechanisms in GaN power devices under high-stress conditions has been a persistent issue, particularly with respect to catastrophic failures difficult to detect through conventional electrical measurements. This study focuses on p-GaN-based high-electron-mobility transistors (HEMT) technology device, subjected to high-stress conditions, to analyze the entire device architecture and mainly the structure of the gate–source bridge. SEM analyses reveal significant structural damage, including cracks and voids, particularly near the metal interconnection lines and GaN buffer layers, whereas Raman spectroscopy highlights distortions in the wurtzite GaN crystal structure. By integrating the spectroscopic and morphological results, useful insights into the GaN device layers interested by the failure mechanisms are provided. These data are useful to optimize the multi-layer stacked structures and then to enhance the GaN HEMTs main characteristics.

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来源期刊

Microelectronics Reliability 工程技术-工程：电子与电气

CiteScore

3.30

自引率

12.50%

发文量

342

审稿时长

68 days

期刊介绍： Microelectronics Reliability, is dedicated to disseminating the latest research results and related information on the reliability of microelectronic devices, circuits and systems, from materials, process and manufacturing, to design, testing and operation. The coverage of the journal includes the following topics: measurement, understanding and analysis; evaluation and prediction; modelling and simulation; methodologies and mitigation. Papers which combine reliability with other important areas of microelectronics engineering, such as design, fabrication, integration, testing, and field operation will also be welcome, and practical papers reporting case studies in the field and specific application domains are particularly encouraged. Most accepted papers will be published as Research Papers, describing significant advances and completed work. Papers reviewing important developing topics of general interest may be accepted for publication as Review Papers. Urgent communications of a more preliminary nature and short reports on completed practical work of current interest may be considered for publication as Research Notes. All contributions are subject to peer review by leading experts in the field.