Abstract: With the advancement of electronic information technology, the size effect in solder joints has become increasingly prominent. However, research on the evolution of electrical properties and microscopic mechanisms in microscale solder joints under electromigration remains notably insufficient. The growth behavior of interfacial intermetallic compound(IMC) and its size effect during the electromigration process of ball grid array(BGA) solder joints with different sizes are systematically examined.. The resistance of solder joints is dynamically and real-time monitored.. During the electromigration process, the IMC thickness at the anode of the solder joint is always greater than that at the cathode, and the larger size of the solder joint is easier to generate more IMC at the interface. The resistance of the solder joint rises and fluctuates in a zigzag or triangular shape during the electromigration. The increase of resistance is due to the expansion of holes and cracks, as well as the growth of a large number of IMCs inside the solder joint. Holes and cracks in the solder joint are found to heal during the electromigration, which reduces the resistance of solder joint. During the electromigration process, the defects inside the solder joints with larger size, such as cracks and holes, are more easily generated and expanded, and the growth of IMC is more intense, resulting in a higher resistance value. The results show that a distinct size effect is observed in BGA solder joints during electromigration, and the relationship between the resistance variation and microstructure evolution of solder joints is revealed.

Key words: dynamic resistance monitoring, size effects, electromigration, BGA solder joints