Title :
Computational simulation of underfill encapsulation of flip-chip ICs. I. Flow modeling and surface-tension effects
Author :
Yang, H. ; Bayyuk, S. ; Krishnan, A. ; Przekwas, A. ; Nguyen, L. ; Fine, P.
Author_Institution :
CFD Res. Corp., Huntsville, AL, USA
Abstract :
This paper presents a computational technique for time-accurate prediction of the filling pattern during underfill encapsulation of flip-chip ICs. In order to accurately track the propagation of the resin front while taking into account the geometry of the underfill cavity, including bumps and edges, as well as all the boundary conditions that are transmitted to the resin front through the air, a two-phase model of the combined flow of resin and air in the underfill cavity is used. The two-phase flowfield is modeled using a Volume-of-Fluid (VOF) methodology embedded in a general-purpose, three-dimensional, flow-solver. A new surface-tension model is developed for computing the capillary-action forces that are exerted on the resin front and which drive the flow in underfill encapsulation processes
Keywords :
capillarity; encapsulation; flip-chip devices; integrated circuit packaging; integrated circuit reliability; surface tension; capillary-action forces; computational simulation; filling pattern; flip-chip ICs; flow modeling; resin front; surface-tension effects; surface-tension model; two-phase model; underfill cavity; underfill encapsulation; volume-of-fluid methodology; Computational modeling; Computer interfaces; Curing; Encapsulation; Filling; Packaging; Resins; Software packages; Thermal stresses; Viscosity;
Conference_Titel :
Electronic Components & Technology Conference, 1998. 48th IEEE
Conference_Location :
Seattle, WA
Print_ISBN :
0-7803-4526-6
DOI :
10.1109/ECTC.1998.678912
