Mechanical loading of flip chip joints before underfill: the impact on yield and reliability

Abstract

The underfill-facilitated migration from ceramic to lower cost laminate substrates has become a powerful enabler of direct chip attach by offering lower cost, greater electrical functionality, and a smaller system footprint over comparable packaging technologies. Once underfilled, flip chip on laminate has proven extremely reliable even in severe automotive environments. However, between the process steps of reflow and underfill cure, unprotected flip chip solder joints assembled to laminate boards are susceptible to damage and breakage if mishandled. Here, the survivability and long-term reliability of flip chip joints was studied over a range of applied strains. Mechanical loading of joints was applied via beam deflections of populated, but nonunderfilled, laminate boards. Electrical continuity was monitored before and after testing to determine when the load applied to the flip chip exceeded the joint fracture strength. The propensity for solder joint fracture was then calculated as a function of solder bump size and also as a function of strain rate. Analysis of the mechanical properties of solder revealed assembly strategies which reduce bump damage and eliminate yield loss during the process steps leading up to underfill cure. Both strained and unstrained units were then underfilled and cycled between −50 and +150 °C. While mechanical damage was evident in bump cross-sections of strained flip chip assemblies, the fatigue lives of underfilled solder joints were found to be independent of the size of mechanical loads applied before underfill.