Title :
Fracture properties of molding compound materials for IC plastic packaging
Author :
Sauber, John ; Lee, Lidia ; Hsu, Shih ; Hongsmatip, Trirat
Author_Institution :
Digital Equipment Corp., Hudson, MA, USA
fDate :
12/1/1994 12:00:00 AM
Abstract :
The technique of linear elastic fracture mechanics (LEFM) was employed to characterize the fracture toughness of different molding compound materials. The effect of fast thermal loading rate, as in a wave soldering condition, was studied by performing the fracture toughness tests at different mechanical loading speeds. The effects of storage conditions and accelerated testing environments were studied by varying the test temperatures from liquid nitrogen temperature to 150°C. Models were built of 208 I/O PQFP devices with cracks in the molding compound at the corner of the die pad. These models were solved to evaluate the effect of CTE mismatches, initial flaw sizes, and die pad delamination on molding compound stress intensity factors. Finite element results were then compared with crack growth measurements from PQFP packages that had been subjected to accelerated thermal cycling
Keywords :
delamination; finite element analysis; fracture toughness testing; integrated circuit packaging; life testing; plastic packaging; thermal expansion; wave soldering; -196 to 150 degC; CTE mismatches; IC plastic packaging; PQFP devices; accelerated testing environments; crack growth measurements; delamination; die pad; fast thermal loading rate; finite element results; flaw sizes; fracture toughness tests; linear elastic fracture mechanics; mechanical loading speeds; molding compound materials; storage conditions; stress intensity factors; thermal cycling; wave soldering condition; Delamination; Life estimation; Nitrogen; Performance evaluation; Plastics; Soldering; Temperature; Testing; Thermal loading; Thermal stresses;
Journal_Title :
Components, Packaging, and Manufacturing Technology, Part A, IEEE Transactions on
