用于密集集成电子系统的嵌入式冷却技术

Thomas E. Sarvey, Yang Zhang, Li Zheng, Paragkumar Thadesar, R. Gutala, Colman Cheung, Arifur Rahman, M. Bakir
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引用次数: 26

摘要

在现代集成系统中,互连和热管理技术已成为制约系统性能的两大主要因素。在本文中,提出了一些技术来解决这些挑战。首先,在与微流体兼容的厚晶圆上展示了低损耗聚合物嵌入过孔。接下来,在组装的2.5D和3D堆栈中演示了用于向微流体散热器输送流体的流体I/ o。然后探讨了2.5D和3D系统中骰子之间的热耦合。最后,通过FPGA演示了微流控散热的实用性,该FPGA采用28nm制程,具有单片集成的微流控散热器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Embedded cooling technologies for densely integrated electronic systems
In modern integrated systems, interconnect and thermal management technologies have become two major limitations to system performance. In this paper, a number of technologies are presented to address these challenges. First, low-loss polymer-embedded vias are demonstrated in thick wafers compatible with microfluidics. Next, fluidic I/Os for delivery of fluid to microfluidic heat sinks are demonstrated in assembled 2.5D and 3D stacks. Then thermal coupling between dice in 2.5D and 3D systems is explored. Lastly, the utility of microfluidic cooling is demonstrated through an FPGA, built in a 28nm process, with a monolithically integrated microfluidic heat sink.
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