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A technical paper titled “Room-Temperature Direct Cu Semi-Additive Plating (SAP) Bonding for Chip-on-Wafer 3D Heterogenous Integration With μLED” was printed by researchers at Tohoku University in Japan.
Abstract:
“This letter describes a direct Cu bonding technology to there-dimensionally integrate heterogeneous dielets based on a chip-on-wafer configuration. 100- μm -cubed blue μ LEDs temporarily adhered on a photosensitive resin are interconnected by semi-additive plating (SAP) without thermal compression bonding. By using SAP bonding, a lot of dielets can be stacked on thin 3D-IC chiplets. The following three key technologies are applied to solve the yield issues of SAP bonding. After pick-and-place assembly, additional coplanarity enhancement eliminates Cu bridges grown to a small gap between the μ LEDs and photosensitive resin. The μ LEDs arrays with sidewalls insulated by room-temperature ozone-ethylene-radical (OER)-SiO2-CVD are successfully bonded on sapphire wafers and a thin 3D-IC with through-Si via (TSV). Further design optimization is required, but partial seed pre-etching works well to increase the yield. Fully integrated module implementation with the 3D-ICs will be the next stage, however, we discuss a superior prospect for yield enhancement toward nearly 100%.”
Find the technical paper here. Published Jan. 2023. A college information article could be discovered here.
Y. Susumago et al., “Room-Temperature Direct Cu Semi-Additive Plating (SAP) Bonding for Chip-on-Wafer 3D Heterogenous Integration With μLED,” in IEEE Electron Device Letters, vol. 44, no. 3, pp. 500-503, March 2023, doi: 10.1109/LED.2023.3237834.
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