TY - GEN
T1 - Thermal Transport Properties of Hybrid Bonding With Passivation
AU - Kim, Hakjun
AU - Hwang, Jae Young
AU - Park, Sangwoo
AU - Kim, Sarah Eunkyung
AU - Joo, Young Chang
AU - Jang, Hyejin
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Recently, 3D hybrid bonding has drawn a lot of interest since it is an essential technology for system scaling by increasing interconnect density. However, 3D stacked structures face challenges in heat dissipation due to the limited exposed area, and the hybrid bonding becomes the main channel for not only power and signal but also heat. While the thermal characteristics of the bonding have been investigated extensively through modeling, the direct measurement remains unexplored due to the intricate structural issues. This investigation focuses on refining the precision of thermal property measurements by modifying bonding structures with a sapphire substrate, thereby facilitating the application of optical pump-probe techniques, such as time-domain thermoreflectance (TDTR). Additionally, it introduces a bidirectional heat transfer model that integrates a transducer layer and tantalum (Ta) diffusion barrier, aiming to surmount challenges in heat transfer measurement and ensure measurement accuracy. The experimental findings encompass sample preparation, validation of the insertion of a tantalum (Ta) diffusion barrier, and thermal transport property analysis using TDTR and bidirectional heat transfer modeling, resulting in the accurate extraction of key parameters and providing extensive insights into the intricate thermal behavior of bonding layers.
AB - Recently, 3D hybrid bonding has drawn a lot of interest since it is an essential technology for system scaling by increasing interconnect density. However, 3D stacked structures face challenges in heat dissipation due to the limited exposed area, and the hybrid bonding becomes the main channel for not only power and signal but also heat. While the thermal characteristics of the bonding have been investigated extensively through modeling, the direct measurement remains unexplored due to the intricate structural issues. This investigation focuses on refining the precision of thermal property measurements by modifying bonding structures with a sapphire substrate, thereby facilitating the application of optical pump-probe techniques, such as time-domain thermoreflectance (TDTR). Additionally, it introduces a bidirectional heat transfer model that integrates a transducer layer and tantalum (Ta) diffusion barrier, aiming to surmount challenges in heat transfer measurement and ensure measurement accuracy. The experimental findings encompass sample preparation, validation of the insertion of a tantalum (Ta) diffusion barrier, and thermal transport property analysis using TDTR and bidirectional heat transfer modeling, resulting in the accurate extraction of key parameters and providing extensive insights into the intricate thermal behavior of bonding layers.
KW - hybrid bonding
KW - thermal transport
KW - time-domain thermoreflectance
UR - https://www.scopus.com/pages/publications/85197737303
U2 - 10.1109/ECTC51529.2024.00264
DO - 10.1109/ECTC51529.2024.00264
M3 - Conference contribution
AN - SCOPUS:85197737303
T3 - Proceedings - Electronic Components and Technology Conference
SP - 1609
EP - 1612
BT - Proceedings - IEEE 74th Electronic Components and Technology Conference, ECTC 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 74th IEEE Electronic Components and Technology Conference, ECTC 2024
Y2 - 28 May 2024 through 31 May 2024
ER -