三维集成电路设计的热机械应力感知管理

Qiaosha Zou, Zhang Tao, E. Kursun, Yuan Xie
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引用次数: 13

摘要

由于硅通孔(tsv)与硅衬底之间的热膨胀系数不匹配以及热梯度升高,热机械应力一直被认为是三维集成电路(3D ic)中最具挑战性的问题之一。为了解决应力问题,我们提出了一种结合设计时和运行时技术的彻底解决方案,以减轻热机械应力和相关的可靠性问题。提出了一种复杂的TSV应力敏感平面图策略,以最大限度地减少晶圆开裂和界面分层的可能性。此外,运行时热管理方案有效地消除了层间较大的热梯度。实验结果表明,由于降低了TSV热负荷,消除了机械损伤热循环模式,可以显著提高三维设计的可靠性。
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Thermomechanical stress-aware management for 3D IC designs
The thermomechanical stress has been considered as one of the most challenging problems in three-dimensional integration circuits (3D ICs), due to the thermal expansion coefficient mismatch between the through-silicon vias (TSVs) and silicon substrate, and the presence of elevated thermal gradients. To address the stress issue, we propose a thorough solution that combines design-time and run-time techniques for the relief of thermomechanical stress and the associated reliability issues. A sophisticated TSV stress-aware floorplan policy is proposed to minimize the possibility of wafer cracking and interfacial delamination. In addition, the run-time thermal management scheme effectively eliminates large thermal gradients between layers. The experimental results show that the reliability of 3D design can be significantly improved due to the reduced TSV thermal load and the elimination of mechanical damaging thermal cycling pattern.
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