Thermal characterization of TSV based 3D stacked ICs

2012 IEEE 21st Conference on Electrical Performance of Electronic Packaging and Systems Pub Date : 2012-10-01 DOI:10.1109/EPEPS.2012.6457910

S. Swarup, S. Tan, Zao Liu

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引用次数: 9

Abstract

This paper studies the thermal impact and characterization of Through Silicon Vias (TSVs) in stacked three dimensional (3D) integrated circuits (ICs) through finite-element based numerical analysis. Realistic 3D stacked ICs are built using a commercial finite-element based modeling and analysis tool, COMSOL. Thermal profiles along with thermal impact of TSVs are studied for two layer and three layer stacked IC structures under practical power inputs. Experimental results show that there is a significant temperature gradient across the stacked dies for both two layer and three layer structures. The cross-layer temperature is seen to grow rapidly from two layer structures to three layer structures with the same power and TSV densities. As a result, stacking of active layers will not be scalable as the maximum temperature can quickly reach the 105 degree Centigrade limit for CMOS technology. Elevated temperatures can make thermal-sensitive reliability issues a major challenge for 3D stacked ICs. Advanced cooling, low power design, better thermal management and new architecture techniques are hence required to keep the temperature in a safe range for stacking more layers onto the chip.

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基于TSV的3D堆叠ic热特性研究

本文采用基于有限元的数值分析方法，研究了堆叠三维集成电路中硅通孔(tsv)的热影响及其特性。逼真的3D堆叠ic是使用基于商业有限元的建模和分析工具COMSOL构建的。研究了两层和三层堆叠集成电路结构在实际输入功率下的热分布和热冲击。实验结果表明，无论是两层结构还是三层结构，叠层模间都存在明显的温度梯度。在相同的功率和TSV密度下，层间温度从两层结构迅速增长到三层结构。因此，有源层的堆叠将无法扩展，因为CMOS技术的最高温度可以迅速达到105摄氏度的极限。高温会使热敏可靠性问题成为3D堆叠ic的主要挑战。因此，需要先进的冷却、低功耗设计、更好的热管理和新的架构技术来将温度保持在安全范围内，以便在芯片上堆叠更多的层。

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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2012 IEEE 21st Conference on Electrical Performance of Electronic Packaging and Systems

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