Performance Analysis of Cylindrical Through Silicon Via with Interfacial Crack

2023 24th International Symposium on Quality Electronic Design (ISQED) Pub Date : 2023-04-05 DOI:10.1109/ISQED57927.2023.10129400

V. Kumari, Maya Chandrakar, M. Majumder

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引用次数: 1

Abstract

A continuous scaling down of technology drives the microelectronics industry towards the nanoscale regime, wherein various fabrication-related defects such as electromigration induced open/short faults, interfacial cracks, and thermal stress-induced leakage problems primarily dominate the overall performance of a through silicon via (TSV). Interfacial cracking plays a pivotal role in the long-term service reliability of the chip among them. On account of these facts, this paper provides equivalent RLGC fault modeling and performance analysis of thermo-mechanical delamination in TSVs known as interfacial cracks. Considering the MOS effect, an analytical expression is derived using defective parameters to analyze the feasibility and reliability of the defected TSVs at different crack widths and heights. Using a driver-via-load (DVL) setup, performance in terms of power dissipation, power delay product (PDP), and dynamic crosstalk delay are analyzed using a CMOS driver. Encouragingly, considering interfacial cracked TSV, power and crosstalk delay are improved by 74.4% and 65.5%, respectively, at a minimum crack length approaching the defect-free condition.

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含界面裂纹的圆柱形硅通孔性能分析

技术的不断缩小推动着微电子工业向纳米级方向发展，其中各种与制造相关的缺陷，如电迁移引起的开/短故障、界面裂缝和热应力引起的泄漏问题，主要主导着硅通孔(TSV)的整体性能。其中，界面开裂对芯片的长期使用可靠性起着举足轻重的作用。考虑到这些事实，本文提供了等效RLGC断层建模和tsv中被称为界面裂缝的热-机械分层的性能分析。考虑MOS效应，推导了缺陷参数的解析表达式，分析了缺陷tsv在不同裂纹宽度和高度下的可行性和可靠性。采用驱动器-过负载(DVL)设置，分析了CMOS驱动器在功耗、功率延迟积(PDP)和动态串扰延迟方面的性能。令人鼓舞的是，考虑界面裂纹的TSV，在最小裂纹长度接近无缺陷的情况下，功率和串扰延迟分别提高了74.4%和65.5%。

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

2023 24th International Symposium on Quality Electronic Design (ISQED)

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