应用流动微量热仪开发填充底层树脂

Proceedings International Symposium on Advanced Packaging Materials Processes, Properties and Interfaces (IEEE Cat. No.01TH8562) Pub Date : 2001-03-11 DOI:10.1109/ISAOM.2001.916606

R. Pearson, D. Welsh, R. Oldak, B. J. McAdams

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引用次数: 0

摘要

采用流动微热法(FMC)对一系列不同化学结构的模型底填树脂进行了表征。FMC允许直接观察分子在表面上的吸附强度。在这种情况下，环氧单体、固化剂和粘合促进剂被吸附在硼硅酸盐玻璃粉上，以预测粘合强度。粘接强度采用不对称双悬臂梁试验机械测量。测量了填充和未填充环氧树脂的粘接强度，并经常与FMC结果相关联。利用扫描电子显微镜和光学显微镜对界面裂纹尖端的塑性损伤机理进行了研究。更大的粘附强度可归因于裂纹尖端附近损伤的增加。这种破坏是由界面上强烈的分子相互作用造成的。

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Application of flow microcalorimetry to develop underfill resins

A series of model underfill resins with different chemical structures have been characterized using flow microcalorimetry (FMC). FMC allows the direct observation of the strength of adsorption of molecules on to a surface. In this case, epoxy monomers, curing agents, and adhesion promoters, were adsorbed on to a borosilicate glass powder in an effort to predict adhesive strength. Adhesive strengths were measured mechanically using an asymmetric double cantilever beam test. Adhesive strengths of filled and unfilled epoxy resins were measured and often correlated to FMC results. Scanning electron and optical microscopy were used to identify mechanisms of plasticity/damage at interfacial crack tips. Greater adhesion strength can be attributed to increased damage near the crack tips. Such damage is enabled by strong molecular interactions at the interface.

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Proceedings International Symposium on Advanced Packaging Materials Processes, Properties and Interfaces (IEEE Cat. No.01TH8562)

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