A study of normal, restoring, and fillet forces and solder bump geometry during reflow in concurrent underfill/reflow flip chip assembly

Author

Zhao, Renzhe ; Zhang, Yun ; Johnson, R. Wayne ; Harris, Daniel K.

Author_Institution

Lab. for Electron. Assembly & Packaging, Auburn Univ., AL, USA

fYear

2001

fDate

2001

Firstpage

699

Lastpage

703

Abstract

Simulation of flip chip solder joints in an underfill environment was performed to evaluate the effect of underfill volume and material properties on concurrent underfill and solder reflow manufacturing technique. Forces during solder reflow, fillet shape and collapsed solder ball geometry after reflow are reported. A multiple ball model was created based on single ball model and underfill fillet studies, to predict die stand-off in the presence of a pre-dispensed, fluxing underfill. The predictions agree with experimental results within 1.5 percent. Modeling allows the prediction of self-centering forces, gap height, and die floating as a function of underfill volume and properties in a no-flow, fluxing underfill assembly process

Keywords

encapsulation; flip-chip devices; reflow soldering; collapsed solder ball geometry; concurrent underfill/reflow flip chip assembly; die floating; die stand-off; fillet forces; flip chip solder joints; fluxing underfill; gap height; multiple ball model; normal forces; restoring forces; self-centering forces; solder bump geometry; underfill volume; Assembly; Bonding; Flip chip; Geometry; Performance evaluation; Predictive models; Semiconductor device modeling; Shape; Solid modeling; Surface tension;

fLanguage

English

Publisher

ieee

Conference_Titel

Electronic Components and Technology Conference, 2001. Proceedings., 51st

Conference_Location

Orlando, FL

ISSN

0569-5503

Print_ISBN

0-7803-7038-4

Type

conf

DOI

10.1109/ECTC.2001.927809

Filename

927809