Title :
Temporary spin-on glass bonding technologies for via-last/backside-via 3D integration using multichip self-assembly
Author :
Hashiguchi, Hironori ; Fukushima, Tetsuya ; Noriki, A. ; Kino, Hitoshi ; Lee, Ki-Won ; Tanaka, T. ; Koyanagi, Mitsumasa
Author_Institution :
Dept. of Bioeng. & Robot., Tohoku Univ., Tohoku, Japan
Abstract :
In this study, we proposed and demonstrated self-assembly-based via-last/backside-via 3D integration using a temporary spin-on glass (SOG) bonding technology. A hydrogenated amorphous silicon (a-Si:H) was employed as a debonding layer. Known good dies (KGDs) were precisely self-assembled right side up on an electrostatic carrier wafer by surface tension of water, and then, the KGDs were fixed by applying DC voltage to the carrier. After that, the KGDs were temporarily bonded and transferred to another support glass wafer on which the a-Si:H and SOG layers were deposited. After multichip thinning, Cu-TSVs were formed on the KGDs. The resulting TSV daisy chains showed good electrical characteristics. The KGDs can be debonded with a 308-nm laser and transferred again to target interposer wafers.
Keywords :
amorphous semiconductors; elemental semiconductors; glass; integrated circuit interconnections; multichip modules; self-assembly; silicon; surface tension; three-dimensional integrated circuits; wafer bonding; wafer level packaging; KGD; SOG; Si; TSV daisy chains; debonding layer; electrostatic carrier wafer; glass wafer; hydrogenated amorphous silicon; known good dies; multichip self-assembly; multichip thinning; self-assembly based via-last-backside-via 3D integration; surface tension; temporary spin-on glass bonding technology; through silicon via; wavelength 308 nm; Bonding; Educational institutions; Glass; Self-assembly; Three-dimensional displays; Through-silicon vias; Vertical cavity surface emitting lasers;
Conference_Titel :
Electronic Components and Technology Conference (ECTC), 2014 IEEE 64th
Conference_Location :
Orlando, FL
DOI :
10.1109/ECTC.2014.6897386
