65纳米Cu/Low-$k$大晶片倒装封装的热机械可靠性优化

IEEE Transactions on Components and Packaging Technologies Pub Date : 2009-12-01 DOI:10.1109/TCAPT.2009.2020696

J. Ong, A. Tay, X. Zhang, V. Kripesh, Y. K. Lim, D. Yeo, K.C. Chan, J.B. Tan, L. Hsia, D. Sohn

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引用次数: 16

摘要

更细间距和更高性能集成电路器件的趋势推动了半导体工业采用铜和低k介电材料。然而，与普通介电材料相比，低k材料具有较低的模量和较差的粘附性。因此，热机械失效是铜/低钾大晶片倒装封装发展的主要瓶颈之一。本文介绍了采用全活性和功能性九金属Cu/low-k层和150 μ m互连间距的C65 nm 21 mm × 21 mm芯片尺寸倒装芯片球栅阵列封装的结构优化设计。本文采用的低钾材料为无孔SiCOH, k值为2.9。采用二维平面应变有限元方法进行了参数化分析，研究了各参数对大型模具封装可靠性的影响，从而得到优化设计方案。为了有一个简单的标准来预测尚未建成的大芯片封装的可靠性，对一些现有的15mm × 15mm的CvJlow-k倒装芯片封装进行了可靠性测试，这些封装除了尺寸不同外与21mm × 21mm的封装相同。发现这些包裹通过了可靠性测试。然后对15mm × 15mm模具进行二维平面应变有限元分析。计算出的低k层的分层应力和临界焊料中每周期的应变能密度耗散(DeltaW)，然后作为设计更大倒装芯片封装的基准。验证了聚合物包封切槽技术的有效性。本文研究了氟硅酸盐玻璃层数、模具厚度、衬底厚度、铜柱高度、衬底类型对低k层和DeltaW中分层应力的影响。然后制作了优化后的大模包试样并进行了可靠性试验。他们都通过了可靠性测试。从这些可靠性测试中，获得了低k层和DeltaW的分层应力的新基准值，可用于大芯片Cu/低k倒装封装的设计。

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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Optimization of the Thermomechanical Reliability of a 65 nm Cu/Low-$k$ Large-Die Flip Chip Package

The trend toward finer pitch and higher performance integrated circuit devices has driven the semiconductor industry to incorporate copper and low-k dielectric materials. However, the low-k materials have lower modulus and poorer adhesion compared to the common dielectric materials. Thus, thermomechanical failure is one of the major bottlenecks in the development of Cu/low-k larger-die flip chip packages. This paper describes the optimization of the structural design of Chartered's C65 nm 21 mm times 21 mm die size flip-chip ball grid array package incorporated with fully active and functional ninemetal Cu/low-k layers and 150 mum interconnect pitch. The lowk material used in this paper is nonporous SiCOH with a k value of 2.9. A parametric study using 2-D plane strain finite element analysis was performed to study the effect of various parameters on the reliability of the large-die package in order to arrive at an optimized design. In order to have a simple criterion to predict the reliability of the yet-to-be-built largedie package, reliability tests were carried out on some existing 15 mm times 15 mm die CvJlow-k flip chip packages which were identical to the 21mm times 21mm die package except for the size. The packages were found to pass the reliability tests. 2-D plane strain finite element analyses were then performed on the 15 mm times 15 mm die. The computed delamination stresses at the low-k layer and the strain energy density dissipation per cycle in the critical solder (DeltaW) were then used as a benchmark for the design of a larger flip chip package. The efficacy of the polymer encapsulated dicing lane technology was established. In this paper, the effect of the number of fluorosilicate glass layers, die thickness, substrate thickness, Cu post height, and underfill type on the delamination stresses in the low-k layer and DeltaW were determined. Specimens of the optimized large-die package were then fabricated and subjected to reliability tests. They were all found to pass the reliability tests. From these reliability tests, new benchmark values of the delamination stresses at the low-k layer and DeltaW are obtained, which can be used to aid in the design of large-die Cu/low-k flip chip packages.

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IEEE Transactions on Components and Packaging Technologies 工程技术-材料科学：综合

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