Title :
Underfill flow as viscous flow between parallel plates driven by capillary action
Author :
Schwiebert, Matthew K. ; Leong, William H.
Author_Institution :
Electron. Assembly Dev. Center, Hewlett-Packard Co., Palo Alto, CA, USA
Abstract :
Epoxy underfill is often required to enhance the reliability of flip-chip interconnects. This study evaluates the flow of filled epoxy underfill materials between parallel plates driven by capillary action. An exact model was developed to understand the functional relationship between flow distance, flow time, separation distance, surface tension, and viscosity for quasi-steady laminar flow between parallel plates. The model was verified experimentally with a typical underfill material. The measured values of flow distance agreed well with the exact model. A new material parameter, the coefficient of planar penetrance, is introduced. This parameter measures the penetrating power of a liquid between parallel plates driven by capillary action. The effectiveness of gravity and vacuum as flow rate enhancements are explored
Keywords :
capillarity; integrated circuit interconnections; integrated circuit packaging; integrated circuit reliability; laminar flow; viscosity; capillary action; epoxy underfill; flip-chip interconnects; flow distance; flow time; functional relationship; gravity; material parameter; parallel plates; planar penetrance; quasi-steady laminar flow; reliability; separation distance; surface tension; underfill flow; vacuum; viscosity; viscous flow; Assembly; Fluid flow measurement; Gravity; Laplace equations; Lead; Milling machines; Navier-Stokes equations; Power measurement; Surface tension; Viscosity;
Conference_Titel :
Electronics Manufacturing Technology Symposium, 1995. 'Manufacturing Technologies - Present and Future', Seventeenth IEEE/CPMT International
Conference_Location :
Austin, TX
Print_ISBN :
0-7803-2996-1
DOI :
10.1109/IEMT.1995.526083
