Study of polyimide coated chip and mold compound adhesion

2016 IEEE 37th International Electronics Manufacturing Technology (IEMT) & 18th Electronics Materials and Packaging (EMAP) Conference Pub Date : 2016-09-01 DOI:10.1109/IEMT.2016.7761977

M. T. Asmah

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引用次数: 1

Abstract

This study investigates the adhesion strength between polyi-mide coated chip and epoxy mold compound (EMC). Polyi-mide is an important material to reduce chip stress and protect the mobility ions from EMC to the chip circuitry that can lead to an electrical failure. However, there was a delamination issue between encapsulation material and polyimide during reliability test. Two samples were prepared named as EMC A (sample without adhesion promoter) and EMC B (sample with adhesion promoter). Prior to curing process, wafers were coated with 7±1 μm thickness of polyimide using spin coating process. Then, samples were cured at 175 °C for 5 hours in oven after molding process. Samples were then soaked in the Autoclave test chamber (ACLV) at 121°C with 100% relative humidity (RH) for 0.5 hour, 1 hour, 1.5 hours and 2 hours to test the sample reliability. Adhesion strength was measured at room temperature and 260 °C. In addition, water absorption with varies moisture sensitivity level (MSL) was carried out. The MSL test was set for three level which were 85 °C / 85% RH, 85 °C / 60% RH and 30 °C / 60% RH for level 1, 2 and 3, respectively. There was a significant different on moisture absorption but less significant in delamination response. Based on the strength test, EMC B showed a gap between polyimide and mold compound after 0.5 hour of ACLV test while no gap was observed for EMC A even after 2 hours of ACLV test. It could be concluded that EMC that formulated with adhesion promoter provided significant factor to the delamination issue compared with EMC without adhesion promoter.

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聚酰亚胺涂层切屑与模具复合附着力的研究

研究了聚酰胺包覆芯片与环氧模复合材料(EMC)的粘附强度。聚酰亚胺是一种重要的材料，以减少芯片应力和保护迁移离子从EMC到芯片电路，可能导致电气故障。然而，在可靠性测试中，封装材料与聚酰亚胺之间存在分层问题。制备了两种样品，分别命名为EMC A(无粘附促进剂样品)和EMC B(有粘附促进剂样品)。在固化前，采用自旋镀膜工艺在晶圆上涂覆7±1 μm厚度的聚酰亚胺。成型后，在175℃的烘箱中固化5小时。然后将样品在121℃、100%相对湿度(RH)的高压灭菌试验箱(ACLV)中浸泡0.5小时、1小时、1.5小时和2小时，以测试样品的可靠性。在室温和260℃下测定粘接强度。此外，还进行了不同湿度敏感等级(MSL)的吸水试验。水平1、水平2和水平3分别设置85°C / 85% RH、85°C / 60% RH和30°C / 60% RH的MSL检验。吸湿性差异显著，分层反应差异不显著。从强度测试来看，EMC B在ACLV试验0.5小时后，聚酰亚胺与模具化合物之间出现了差距，而EMC a在ACLV试验2小时后，也没有出现差距。由此可见，与不含粘结促进剂的EMC相比，添加粘结促进剂的EMC对分层问题起着显著的影响作用。

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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来源期刊

2016 IEEE 37th International Electronics Manufacturing Technology (IEMT) & 18th Electronics Materials and Packaging (EMAP) Conference

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