Carbon-based patterned heat spreaders for thermal mitigation of wire bonded packages

2017 23rd International Workshop on Thermal Investigations of ICs and Systems (THERMINIC) Pub Date : 2017-09-01 DOI:10.1109/THERMINIC.2017.8233830

J. Colonna, R. Prieto, P. Coudrain, Y. Hallez, D. Campos, O. Le-Briz, R. Franiatte, C. Brunet-Manquat, C. Chancel, V. Rat

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引用次数: 3

Abstract

Thermal dissipation is a major concern in microelectronics, especially for compact packages and 3D circuits where the dense stacking of thin silicon layers leads to a significant increase of heat densities. Direct hybrid bonding is considered as one of the most promising technologies for future 3D-ICs. Its face-to-face structure allows significant inter-connexion capabilities but it also implies increased thermal densities that will be reflected in both tiers due to the lack of insulating barriers. A specific test vehicle for 3D hybrid bonding including heaters and temperature sensors on each tiers has been fabricated and characterized. Several packaging configurations including different silicon thicknesses, substrate thermal design or the integration of a patterned graphite heat spreader have been tested. The best results were obtained with the integration of the graphite heat spreader which led to a reduction in thermal resistance by 11%. These experimental results have been retro-simulated to establish a thermal model. This model was then used to analyse the heat path and explore the thermal impact of the different packaging parameters.

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碳基图案热扩散器，用于导线粘合封装的热缓解

散热是微电子领域的一个主要问题，特别是对于紧凑封装和3D电路，其中薄硅层的密集堆叠导致热密度显著增加。直接杂化键合被认为是未来3d集成电路最有前途的技术之一。它的面对面结构允许显着的互连能力，但也意味着由于缺乏绝缘屏障而增加的热密度将反映在两层中。三维混合键合的具体测试车辆包括加热器和温度传感器在每层已经制造和表征。已经测试了几种封装配置，包括不同的硅厚度，衬底热设计或图案化石墨散热器的集成。石墨导热片的集成效果最好，热阻降低了11%。对这些实验结果进行了模拟，建立了热模型。然后利用该模型分析了不同封装参数的热路径和热影响。

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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2017 23rd International Workshop on Thermal Investigations of ICs and Systems (THERMINIC)

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