Designer heat spreading materials and composites

2007 12th International Symposium on Advanced Packaging Materials: Processes, Properties, and Interfaces Pub Date : 2007-10-01 DOI:10.1109/ISAPM.2007.4419928

A. J. Amaro, K. Murthy

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引用次数: 1

Abstract

A solid-state system model of “Designer” thermal conducting nano/micro materials used for more effective heat spreading in electronic packaging manufacture is described. The “Designer” materials are much lighter (sp.gr. 2.5g/cc vs. 9.2g/cc) and stronger (modulus 500–820Gpa vs 120GPa) than copper. The material has a coefficient of thermal expansion (1×10−6 vs. 17×10−6) much higher thermal conductivity (500–1200W/mK vs. 390W/mK) and greater heat spreading capabilities. In addition there is the ability to control the thermal conductivity, coefficient of thermal expansion and thermal spreading coefficient in any of the three material dimensions. A brief description characterizing the material and its manufacturing process is here-within. To illustrate the performance gain of using these materials, the base plate of Intel’s CPU Cooler CL-P0030 heat-sink is chosen as an example of a high-heat source cooling device i.e. ≫100W/cm2. Heat greater than 100Wm2 is equivalent to the concentrated focused energy of ≫1000 Suns. (electronic devices melt in seconds without proper cooling) This is a macro example of a replacement for the thermal conducting packaging material structures currently used in electronics.

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设计散热材料和复合材料

描述了一种用于电子封装制造中更有效散热的“设计师”导热纳米/微材料的固态系统模型。“设计师”材料要轻得多(sp.gr.)。2.5g/cc vs. 9.2g/cc)，比铜更强(模量500-820Gpa vs 120GPa)。该材料的热膨胀系数(1×10−6 vs. 17×10−6)更高的导热系数(500-1200W /mK vs. 390W/mK)和更大的散热能力。此外，还有控制导热系数，热膨胀系数和热扩散系数在任何三个材料维度的能力。下面是对该材料及其制造工艺的简要说明。为了说明使用这些材料的性能增益，以Intel的CPU Cooler CL-P0030散热器的底板为例，选用高热源冷却装置，即:100W/cm2。大于100Wm2的热量相当于1000太阳的集中聚焦能量。(电子设备在没有适当冷却的情况下几秒钟就会融化)这是目前电子产品中使用的导热封装材料结构的一个宏观替代例子。

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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2007 12th International Symposium on Advanced Packaging Materials: Processes, Properties, and Interfaces

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