Co-design of micro-fluidic heat sink and thermal through-silicon-vias for cooling of three-dimensional integrated circuit

Bing Shi, Ankur Srivastava, A. Bar-Cohen
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引用次数: 6

Abstract

Three-dimensional integrated circuits (3D-ICs) bring about new challenges to chip thermal management because of their high heat densities. Micro-channel-based liquid cooling and thermal through-silicon-vias (TSVs) have been adopted to alleviate the thermal issues in 3D-ICs. Thermal TSV enables higher interlayer thermal conductivity thereby achieving a more uniform thermal profile. Although somewhat effective in reducing temperatures, they are limited by the nature of the heat sink. On the other hand, micro-channel-based liquid cooling is significantly capable of addressing 3D-IC cooling needs, but consumes a lot of extra power for pumping coolant through channels. This study proposes a hybrid 3D-IC cooling scheme which combines micro-channel liquid cooling and thermal TSV with one acting as heat removal agent, whereas the other enabling beneficial heat conduction paths to the micro-channel structures. The experimental results show that the proposed hybrid cooling scheme provides much better cooling capability than using only thermal TSVs, although consuming 56% less cooling power compared with pure micro-channel cooling.
微流控散热器与三维集成电路散热通孔的协同设计
三维集成电路的高热密度给芯片热管理带来了新的挑战。采用基于微通道的液体冷却和热通硅通孔(tsv)来缓解3d集成电路中的热问题。热TSV使层间导热系数更高,从而实现更均匀的热剖面。虽然在降低温度方面有些效果,但它们受到散热器性质的限制。另一方面,基于微通道的液体冷却明显能够满足3D-IC的冷却需求,但通过通道泵送冷却剂会消耗大量额外的功率。本研究提出了一种混合3D-IC冷却方案,该方案结合了微通道液冷和热TSV,其中一种作为除热剂,而另一种为微通道结构提供有益的热传导路径。实验结果表明,该混合冷却方案的冷却功率比纯微通道冷却方式低56%,但比单纯热通道冷却方式的冷却性能要好得多。
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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