ANALYSIS AND MODELING OF UNDERFILL FLOW DRIVEN BY CAPILLARY ACTION IN FLIP-CHIP PACKAGING

Flip-chip underfilling is a technology by which silica-filled epoxy resin is used to fill the micro-cavity between a silicon chip and a substrate, by dispensing the liquid encapsulant at elevated temperatures along the periphery of one or two sides of the chip and then allowing capillary action to draw the material into the gap. Since the chip, underfill material, and substrate solidify together as one unit, thermal stresses on solder joints during the temperature cycling (which are caused by a mismatch in the coefficients of thermal expansion between the silicon chip and the organic substrate) can be redistributed and transferred away from the fragile bump zone to a more strain-tolerant region. Modeling of the flow behaviour of a fluid in the underfill process is the key to this technology. One of the most important drawbacks in the existing models is inadequate treatment of non-Newtonian fluids in the underfill process in the development of both analytical models and numerical models. Another important drawback is the neglect of the presence of solder bumps in the existing analytical models.