Dissipating heat from hot spot using a new nano thermal interface material

The need for faster, smaller, more reliable and efficient products has resulted in increased heat generated in microelectronic components. Removal of the heat generated is an important issue in electronic packaging. Therefore, a novel Nano-Thermal Interface Material was developed to improve this. Th...

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Hauptverfasser:	Shuangxi Sun, Wei Mu, Yan Zhang, Carlberg, Bjorn, Lilei Ye, Liu, Johan
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Materials Metals Microassembly Resistance heating Thermal resistance
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creator	Shuangxi Sun Wei Mu Yan Zhang Carlberg, Bjorn Lilei Ye Liu, Johan
description	The need for faster, smaller, more reliable and efficient products has resulted in increased heat generated in microelectronic components. Removal of the heat generated is an important issue in electronic packaging. Therefore, a novel Nano-Thermal Interface Material was developed to improve this. This paper aims at studying the thermal performance of the new nano-structured polymer-metal composite film (Nano-TIM) in application for dissipating around hot spots which exist in non-uniform power generation. Through semiconductor process and Micron-RTD principle, 55mm 2 thermal test chips were developed to serve as a heat source for detecting the heat dissipation effect of the Nano-TIM. T3Ster test system and IR Camera were used to measure partial thermal resistance of the 50 and 75 um Nano-TIM layer and study the spread of different hot spot positions in 1010mm 2 power chip. We also studied the hot spot dissipation effect under different die attach areas with the Nano-TIM. According to the results of this study, this new class of Nano-TIM can meet the high requirements for hot spot dissipation of highly non-uniform power distribution in electronics packaging.
doi_str_mv	10.1109/ICEPT-HDP.2012.6474593
format	Conference Proceeding
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subjects	Materials Metals Microassembly Resistance heating Thermal resistance
title	Dissipating heat from hot spot using a new nano thermal interface material
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