In this study, the diffusion behavior and microstructural evolution of Cu-Sn intermetallics at eutectic Sn-Pb solder/copper substrate interface of PBGA solder joints was studied. The PBGA solder joints were formed by different profiles, which was devised to have the same “heating factor”—the integral of the measured temperature above the liquidus (183°C) with respect to dwell time in the reflow profile, but to have different conveyor speeds. Using the theory of heat transmission, it is shown that the solder joint cooling rate during solidification increases with increasing conveyor speed. As a result, the “crystallization degree” of the solder joint microstructure decreased with the increasing of cooling rate. The thickness of IMC layer increased with extension of aging time. The growth of IMC is a diffusion-controlled process, i.e., tin diffuses into copper, and the diffusion coefficient in the “disordered region” Db is much bigger than that in the “crystallization region” Dl, so the IMC growth rate of solder joint with faster cooling rate was larger. On the other hand, although Db>Dl at all temperatures, the difference increases as temperature decrease, consequently, the difference of IMC thickness growth among different cooling rate solder joints varied according to the aging temperature.

Issue Section:
Technical Briefs
Keywords:
Plastic BGA, Solder Joint, Cooling Rate, Cu-Sn Intermetallics, Intermetallic Compound Growth, copper alloys, tin alloys, reflow soldering, ball grid arrays, plastic packaging, annealing, chemical interdiffusion, crystallisation, solidification, ageing
Topics:
Cooling, Crystallization, Diffusion (Physics), Intermetallic compounds, Solder joints, Solders, Tin, Temperature, Solidification, Ball-Grid-Array packaging, Copper
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