使用铜柱凸块的多芯片到 PCB 倒装芯片封装的组装研究

IF 2.3 3区 工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Zhibo Cao;Jens Lehmann;Bruno Heusdens;Emre Can Durmaz;Patrick Krüger;Matthias Wietstruck;Norbert Herfurth;Awwal Adeniyi Adesunkanmi;Corrado Carta;Mehmet Kaynak
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引用次数: 0

摘要

本文全面研究了基于铜柱的多芯片倒装芯片封装与低成本印刷电路板基板的组装技术。这种封装被视为 60 GHz 以下毫米波宽带应用的高性价比解决方案。比较了三种主要的倒装芯片组装方法:大规模回流焊、铜柱热压焊和金-铜热压焊(TCB)。在这三种组装方法中,对用于组装的样品和组装条件进行了系统比较。具体而言,在不同的组装方法中,使用了带焊帽和不带焊帽的铜柱、不同阻焊层厚度的印刷电路板基板、不同玻璃化转变温度的印刷电路板基板以及不同的粘接压缩力。组装完成后,通过蜿蜒菊花链电阻测量法检测组装良率和每个凸点的接触电阻,并通过剪切测试和横截面检测整个芯片和单个凸点的粘合质量。研究结果表明,尽管回流焊接的成品率略低,但它在大批量、高成本效益组装方面具有优势,而金-铜热压焊板的成品率非常高,但产量却有所降低。而铜柱热压焊与其他两种方法相比并不具有优势。这项细致的研究提高了所讨论的封装方法的可用性,为该领域未来的技术进步奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Assembly Investigation of a Multichip to PCB Flip-Chip Package Using Cu Pillar Bumps
This article conducts a comprehensive investigation of the assembly technologies of a Cu pillar-based multichip flip-chip package with low-cost PCB substrates. Such a package is considered as a cost-effective solution for mm-wave broadband applications below 60 GHz. Three main trend flip-chip assembly methods are compared: mass reflow soldering, Cu pillar thermocompression soldering, and Au-Cu thermocompression bonding (TCB). Within these three assembly approaches, both the samples used for assembly and the assembly conditions are systematically compared. Specifically, Cu pillars with and without solder caps, PCB substrates with different solder mask thicknesses, PCB substrates with different glass transition temperatures, and different bonding compression forces are carried out in different assembly approaches. After the assembly, the assembly yield and contact resistance per bump are examined by meander daisy chain resistance measurement and the bonding qualities of both the whole chip and individual bumps are inspected using shear testing and cross sectioning. Findings reveal that reflow soldering offers advantages for high-volume, cost-effective assemblies despite a slightly lower yield, and the Au-Cu TCB exhibits a very high yield with diminished throughput. Whereas, Cu pillar thermocompression soldering does not manifest advantages over the other two approaches. This meticulous investigation enhances the accessibility of the discussed packaging approach, contributing to the groundwork for future technological advancements in this domain.
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来源期刊
IEEE Transactions on Components, Packaging and Manufacturing Technology
IEEE Transactions on Components, Packaging and Manufacturing Technology ENGINEERING, MANUFACTURING-ENGINEERING, ELECTRICAL & ELECTRONIC
CiteScore
4.70
自引率
13.60%
发文量
203
审稿时长
3 months
期刊介绍: IEEE Transactions on Components, Packaging, and Manufacturing Technology publishes research and application articles on modeling, design, building blocks, technical infrastructure, and analysis underpinning electronic, photonic and MEMS packaging, in addition to new developments in passive components, electrical contacts and connectors, thermal management, and device reliability; as well as the manufacture of electronics parts and assemblies, with broad coverage of design, factory modeling, assembly methods, quality, product robustness, and design-for-environment.
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