Ti/Si interface enabling complementary metal oxide semiconductor compatible, high reliable bonding for inter-die micro-fluidic cooling for future advanced 3D integrated circuit integration

Cheemalamarri, Hemanth Kumar and Bonam, Satish and Vanjari, Siva Rama Krishna and Singh, Shiv Govind (2020) Ti/Si interface enabling complementary metal oxide semiconductor compatible, high reliable bonding for inter-die micro-fluidic cooling for future advanced 3D integrated circuit integration. Journal of Micromechanics and Microengineering, 30 (105005). ISSN 0960-1317

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Abstract

Among the advanced integrated circuit (IC) integration methods, three-dimensional heterogeneous integration with through-silicon via (TSV) technology showed great potential towards the system-level integration with an increased interconnect density in a smaller footprint. However, the heat mitigation across several dies remains a critical issue in this technology with the utilization of vertical dimension, and the distributed hotspots in 3D ICs generating heat-fluxes up-to hundreds of W cm-2 to few thousands of W cm-2. To accomplish such hotspots, micro-fluidic cooling was recognized as a promising approach. In light of this, herein, we propose a facile approach of micro-fluidic integration in between stacked dies, which facilitates inter-die cooling. The integration achieved through silicide (Ti/Si) assisted thermo-compression bonding and here, the bonding conditions were optimized by considering the temperature, pressure, surface roughness, and the thickness of deposited titanium films for glass-silicon and silicon-silicon stacks. The reliability assessment of stacked dies was performed using confocal scanning acoustic microscopy, pull test analysis, and cross-sectional field emission scanning electron microscopy (FESEM). The mechanism of titanium diffusion across the bonding interface suggested the requirement of the titanium thickness of two proposed stacking methods, and was studied using FESEM cross-sectional elemental distribution analysis and observed the interface mechanism. Also, we fabricated the successful integration of fine (100 µm) micro channels with a 200 µm pitch across multi stacked layers.

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IITH Creators:
IITH CreatorsORCiD
Vanjari, Siva Rama KrishnaUNSPECIFIED
Singh, Shiv Govindhttp://orcid.org/0000-0001-7319-879X
Item Type: Article
Uncontrolled Keywords: inter-die micro-fluidic cooling, silicide bonding, thermo-compression bonding, tightly sealed encapsulation, Three dimensional integrated circuits, Complementary metal-oxide-semiconductor compatible
Subjects: Electrical Engineering
Electrical Engineering > Wireless Communication
Electrical Engineering > Process Control
Electrical Engineering > Power System
Electrical Engineering > Automation & Control Systems
Electrical Engineering > Electrical and Electronic
Electrical Engineering > Instruments and Instrumentation
Divisions: Department of Electrical Engineering
Depositing User: . LibTrainee 2021
Date Deposited: 27 Jun 2022 04:04
Last Modified: 27 Jun 2022 04:04
URI: http://raiithold.iith.ac.in/id/eprint/7812
Publisher URL: http://doi.org/10.1088/1361-6439/ab9f00
OA policy: https://v2.sherpa.ac.uk/id/publication/11321
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