Inverse opals for fluid delivery in electronics cooling systems

Fourteenth Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) Pub Date : 2014-05-27 DOI:10.1109/ITHERM.2014.6892356

Thomas J. Dusseault, Julie Gires, M. Barako, Y. Won, D. Agonafer, M. Asheghi, J. Santiago, K. Goodson

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引用次数: 12

Abstract

We report the fabrication and fluid flow characterization of a class of open-cell copper foams known as copper inverse opals (CIOs). This material has finely controlled structure at the pore level, which may enable its use in microscale heat exchangers for microelectronics cooling. We fabricated CIOs by electrodepositing copper around a sacrificial template of packed polystyrene microspheres. We then removed the CIOs from their substrates and used electroetching to vary the pore structure and porosity. We characterized the geometry of the samples at various stages of fabrication with visual inspection and image analysis of scanning electron micrographs. We characterized the permeability with a through-plane flow rig and developed computational models for fluid flow in ideal face-centered cubic and hexagonally close-packed unit cells. Here we report the simulated and experimentally measured values of permeability. We also report experimental challenges that arise from the microscale dimensions of the samples.

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电子冷却系统中流体输送用反蛋白石

我们报告了一类被称为铜逆蛋白石(cio)的开孔泡沫铜的制备和流体流动特性。该材料在孔隙水平上具有精细控制的结构，这可能使其能够用于微电子冷却的微型热交换器。我们通过在聚苯乙烯微球牺牲模板周围电沉积铜来制备cio。然后，我们从衬底上去除cio，并使用电蚀刻来改变孔隙结构和孔隙率。我们用扫描电子显微照片的视觉检查和图像分析表征了样品在制造的各个阶段的几何形状。我们通过平面流动装置表征了渗透率，并建立了理想面心立方和六边形密排单元格的流体流动计算模型。这里我们报告渗透率的模拟值和实验测量值。我们还报告了来自样品的微尺度尺寸的实验挑战。

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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Fourteenth Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm)

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