Abstract

A multistrata dynamic random access memory (DRAM) vertically integrated with a complementary metal oxide semiconductor (CMOS) logic device using through-silicon vias (TSVs) and a unique interposer technology was developed for high-performance, power-efficient, and scalable computing. SMAFTI (SMArt chip connection with FeedThrough Interposer) technology, featuring an ultra-thin organic interposer with high-density feedthrough conductive vias, was used for interconnecting the three-dimensionally stacked DRAM and the CMOS logic device . A DRAM-compatible TSV manufacturing process was realized through the use of a ldquovia-firstrdquo process and highly doped poly-Si TSVs for vertical traces inside memory dice. A multilayer ultra-thin die stacking process with micro-bump interconnection using a solid-liquid interdiffusion technique was also developed. The thermal aging reliability of the micro-bump interconnection was evaluated by a unique analysis method and its basic reliability was confirmed. Finally, we fabricated a prototype package including stacked DRAM and a CMOS logic device, and observed the combined operation. High-speed 3 Gbit/s signals were successfully transmitted through the fine interposer between the memory and logic.