Thermo-Mechanical Process Emulation and Sensitivity Analysis of Wafer Warpage after Reconstitution in Fan-out Packaging

2019 International Conference on Electronics Packaging (ICEP) Pub Date : 2019-04-01 DOI:10.23919/ICEP.2019.8733604

Cheng-Ying Yang, Kuo-Shen Chen, Tian-Shian g Yang, T. Chiu, Ching-Jenq Ho

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引用次数: 3

Abstract

Wafer reconstitution fan-out is a vital process for serving as a buffer to decouple the processing developments between IC fabrication and electronics packaging. By this approach, the IC packaging is then independent from the chip processing. However, such a process brings numerous mechanical loadings during molding and curing phases. In this work, it is desired to examine the key factor of reconstituted wafer warpage by performing solid thermo-mechanical analyses. To have a deeper insight, simplified 2D and detailed 3D finite element analyses have been constructed to mimic the entire Recon process. Detail thermo-mechanical processing steps are then emulated by these finite element models. After model validation, systematic parametric studies are then performed to investigate the controlling factors for dominating the wafer warpage. The simulation results indicated that the thermal expansion coefficients and the Young’s modulus of molding compounds could be the dominated factor. By choosing compounds with more desirable above-mentioned mechanical properties, it is expected that a 20 to 30 percentage reduction of warpage can be achieved.

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扇形封装中晶圆重构后翘曲的热-机械过程仿真及灵敏度分析

晶圆重构扇出是一个至关重要的过程，作为缓冲，以分离IC制造和电子封装之间的加工发展。通过这种方法，IC封装就独立于芯片处理。然而，这种工艺在成型和固化阶段带来了大量的机械负荷。在这项工作中，希望通过进行固体热力学分析来检查重构晶圆翘曲的关键因素。为了获得更深入的了解，我们构建了简化的2D和详细的3D有限元分析来模拟整个Recon过程。然后用这些有限元模型模拟详细的热机械加工步骤。模型验证后，系统的参数研究，然后进行调查控制因素主导晶圆翘曲。模拟结果表明，复合材料的热膨胀系数和杨氏模量是影响成形性能的主要因素。通过选择具有更理想的上述机械性能的化合物，预计可以实现20%至30%的翘曲减少。

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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2019 International Conference on Electronics Packaging (ICEP)

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