Title :
Prototype of multi-stacked memory wafers using low-temperature oxide bonding and ultra-fine-dimension copper through-silicon via interconnects
Author :
Wei Lin ; Faltermeier, J. ; Winstel, K. ; Skordas, S. ; Graves-Abe, T. ; Batra, P. ; Herman, K. ; Golz, J. ; Kirihata, T. ; Garant, J. ; Hubbard, A. ; Cauffman, K. ; Levine, T. ; Kelly, J. ; Priyadarshini, D. ; Peethala, B. ; Patlolla, R. ; Shoudy, M. ; D
Author_Institution :
IBM Corp. Syst. & Technol. Group, Albany, NY, USA
Abstract :
Reported for the first time is proof-of-concept multi-stacking of memory wafers based on low-temperature oxide wafer bonding using novel design and integration of two types of ultra-fine-dimension copper TSV interconnects. The combined via-middle (intra-via) and via-last (inter-via) strategy allows for the greatest degree of interconnectivity with the tightest allowable pitches and permits a highly integrated interconnect system across the stack. In combination with the successful metallization of the ultra-fine-dimension TSVs, the present work has shown the viability to extend the perceived TSV technology beyond the ITRS roadmap.
Keywords :
copper; integrated circuit interconnections; integrated circuit metallisation; integrated memory circuits; low-temperature techniques; three-dimensional integrated circuits; wafer bonding; ITRS roadmap; integrated interconnect system; intervia strategy; intravia strategy; low-temperature oxide wafer bonding; multistacked memory wafer; ultrafine-dimension TSV metallization; ultrafine-dimension copper through-silicon via interconnect; via-last strategy; via-middle strategy; Bonding; Copper; Metallization; Stacking; Three-dimensional displays; Through-silicon vias; Wafer bonding; 3D; DRAM; TSV; oxide bonding; wafer stacking;
Conference_Titel :
SOI-3D-Subthreshold Microelectronics Technology Unified Conference (S3S), 2014 IEEE
Conference_Location :
Millbrae, CA
DOI :
10.1109/S3S.2014.7028246
