Process integration of solder bumps and Cu pillar microbumps on 2.5D fine pitch TSV interposer

2013 IEEE 15th Electronics Packaging Technology Conference (EPTC 2013) Pub Date : 2013-12-01 DOI:10.1109/EPTC.2013.6745756

S. L. Pei-Siang, L. Ding, Mingbin Yu, M. Ding, Sorono Dexter Velez, V. S. Rao

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引用次数: 3

Abstract

The use of portable electronic devices like smart phones and tablets results in high demand for more function, smaller dimensions and reduced power consumption requirements. To meet these challenges, electronic package design uses thinner chips with fine pitch bumping. There has been active development in 2.5D and 3D IC packages with through silicon via (TSV). Tighter interconnection in addition to the increased density in the circuit in 2.5D and 3D IC systems provide higher performance with lower power consumption [1]. In addition, the down scaling trend of CMOS technology beyond 28nm node requires smaller chip size for a given input/output (I/O) count, pushing the interconnect pitch smaller and smaller. When the bump pitch is less than 50μm and the gap between the die and substrate is lesser than 25μm, traditional capillary underfill (CUF) material is likely to require a vacuum or pressure assisted process to pull the underfill and fill the gaps without any voids [2]. The narrower gap also makes flux cleaning after reflow more challenging. The development of wafer-level underfills can bring the financial benefits of wafer-level processing to flip chip assembly and packaging. The flip chip assembly is the application of underfill at the wafer level, eliminating the dispense, flow, and separate cure steps associated with assemblies utilizing capillary-flow underfills. In addition, the wafer-level material should include fluxing capabilities similar to no-flow underfills [3]. In this paper we describe the assembly process and challenges of the 100μm thin 2.5D TSV Si interposer to the test substrate and the assembly of three different test chips onto TSV Si interposer using capillary underfill and WL-UF (NST series from Nissan Chemical Industries, Ltd). The TSV Si interposer provides high density multilevel routing on the frontside of the wafers and through-silicon vias (TSVs) to connect the frontside metallization with the backside metallization for connection to the PCB [4].

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2.5D细间距TSV中间层焊料凸点与铜柱微凸点的工艺集成

智能手机和平板电脑等便携式电子设备的使用导致了对更多功能、更小尺寸和更低功耗要求的高需求。为了应对这些挑战，电子封装设计采用更薄的芯片和精细的间距碰撞。通过硅通孔(TSV)的2.5D和3D IC封装一直在积极发展。在2.5D和3D IC系统中，更紧密的互连以及电路密度的增加提供了更高的性能和更低的功耗[1]。此外，超过28nm节点的CMOS技术的缩小趋势要求在给定的输入/输出(I/O)计数下更小的芯片尺寸，从而推动互连间距越来越小。当凹凸间距小于50μm，且模具与衬底之间的间隙小于25μm时，传统的毛细底填料(CUF)材料可能需要真空或压力辅助工艺来拉取底填料并填充间隙，而不会产生任何空隙[2]。更窄的间隙也使回流后的助焊剂清洁更具挑战性。晶圆级底填料的发展可以为倒装芯片组装和封装带来晶圆级加工的经济效益。倒装芯片组件是在晶圆级应用下填充，消除了与利用毛细管流下填充的组件相关的分配、流动和单独固化步骤。此外，晶圆级材料应具有类似于无流底填土的助熔能力[3]。在本文中，我们描述了100μm薄2.5D TSV Si中间层到测试基板的组装过程和挑战，以及使用毛细管下填充和WL-UF(日产化学工业有限公司的NST系列)将三种不同的测试芯片组装到TSV Si中间层上。TSV Si中间层在晶圆的正面提供高密度多层布线，并通过硅通孔(TSV)将正面金属化与背面金属化连接到PCB上[4]。

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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2013 IEEE 15th Electronics Packaging Technology Conference (EPTC 2013)

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