Research of SEB effects in trench IGBT based on the TCAD simulation

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

Microelectronics Reliability Pub Date : 2024-10-07 DOI:10.1016/j.microrel.2024.115517

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Abstract

In this paper, based on TCAD simulation, a detailed investigation of the SEB failure mechanism of trench IGBTs featuring a deep trench with slanted side-walls structure is conducted for the first time by studying the temporal evolution of electrostatic potential, impact ionization, electric field, current density, and hole concentration distributions. The study reveals that heavy ion irradiation can induce the turning-on of inherent parasitic transistors, leading to the formation of latch-up and consequently SEB. Firstly, the peak electric field transfer leads to high-level impact ionization at the homojunction, injecting ionized electrons into the base-neutral region to turn on the parasitic PNP transistor. Secondly, ionized holes flow through the P-well towards the emitter, diminishing the potential barrier between the P-well and the N+ source region, thus activating the parasitic NPN transistor. Finally, with the parasitic NPN transistor remaining forward-biased, it continuously supplies electron current to the parasitic PNP transistor, thereby sustaining its operation. In summary, the conclusions obtained from the study can provide important references for a deeper understanding of the failure mechanisms of trench IGBT devices in harsh radiation environments.

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基于 TCAD 仿真的沟槽式 IGBT SEB 效应研究

本文基于 TCAD 仿真，通过研究静电势、冲击电离、电场、电流密度和空穴浓度分布的时间演变，首次对具有斜侧壁结构的深沟槽 IGBT 的 SEB 失效机制进行了详细研究。研究发现，重离子辐照可诱导固有寄生晶体管开启，从而形成闩锁，进而导致 SEB。首先，峰值电场转移导致同源结发生高水平冲击电离，将电离电子注入基极中性区，从而开启寄生 PNP 晶体管。其次，电离空穴通过 P 阱流向发射极，减小 P 阱和 N+ 源区之间的势垒，从而激活寄生 NPN 晶体管。最后，寄生 NPN 晶体管保持正向偏压，不断向寄生 PNP 晶体管提供电子电流，从而维持其工作。总之，该研究得出的结论可为深入了解严酷辐射环境下沟槽式 IGBT 器件的失效机制提供重要参考。

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

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.