Guidelines for Area Ratio between Metal Lines and Vias to Improve the Reliability of Interconnect Systems in High-Density Electronic Devices

Hong, Tae Yeong; Kim, Sarah Eunkyung; Park, Jong Kyung; Hong, Seul Ki

doi:10.3390/electronics12214403

Electronics

2023

DOI: 10.3390/electronics12214403

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Guidelines for Area Ratio between Metal Lines and Vias to Improve the Reliability of Interconnect Systems in High-Density Electronic Devices

Tae Yeong Hong,

Sarah Eunkyung Kim,

Jong Kyung Park

et al.

Abstract: This research was conducted in the context of the semiconductor market, with a demand for high-performance and highly integrated semiconductor systems that simultaneously enhance performance and reduce chip size. Scaling down the metal line and via in back-end-of-line (BEOL) structures is essential to efficiently deliver power to scaling down devices. This study utilized the finite element method (FEM) simulation technique to model the heat and current distribution for enhancing the efficiency of scaled-down s… Show more

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2024

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Cited by 3 publications

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Effects of electrolyte flow direction on height difference in electroplated Cu microstructures for fine-pitch RDL

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Reducing Interface Resistance in Semiconductor System Through the Integration of Graphene

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2024

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In the quest to improve overall semiconductor system performance as scaling down continues, reducing resistance in interconnects and bonding interfaces has become a critical focus. This study explores the use of graphene, a highly conductive 2D material, as an interfacial layer between metal and dielectric layers to enhance adhesion and stability while reducing contact resistance. Graphene’s excellent adhesion properties make it a promising candidate for improving bonding strength at metal–dielectric interfaces. We investigated the following two approaches: direct growth of graphene via chemical vapor deposition and the transfer of pre-grown graphene onto the metal surface. The contact resistance characteristics of both methods were analyzed, with results indicating that graphene effectively enhances the bonding interface while significantly lowering contact resistance. These findings suggest that incorporating graphene as an interfacial material could lead to improved performance in advanced semiconductor devices, particularly in applications like hybrid bonding and interconnect technology.

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Analysis of Signal Transmission Efficiency in Semiconductor Interconnect and Proposal of Enhanced Structures

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As the demand for high-density, high-performance technologies in semiconductor systems increases, efforts are being made to mitigate and optimize the issues of high current density and heat generation within interconnects to ensure reliability. While interconnects are the most fundamental pathways for transmitting current signals, there has been relatively little research conducted on them compared to individual unit devices from the perspective of overall system performance. However, as integration density increases, the amount of loss in interconnects also rises, necessitating research and development to minimize these losses. In this study, we propose a method to analyze power efficiency by utilizing the differences between simulation results and measured results of interconnect structures. We confirmed that the difference between theoretical resistance values and actual measured values varies with the contact area ratio between metal lines and vias, and we analyzed the power efficiency based on these differences. Using the findings, we proposed and validated a structure that can improve power efficiency. This study presents a method to analyze power efficiency and suggests ways to achieve higher power efficiency within the limited specifications of interconnects. This contributes to enhancing power efficiency and ensuring reliability, thereby preserving the performance of the overall system in highly integrated semiconductor systems.

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Guidelines for Area Ratio between Metal Lines and Vias to Improve the Reliability of Interconnect Systems in High-Density Electronic Devices

Cited by 3 publications

References 28 publications

Effects of electrolyte flow direction on height difference in electroplated Cu microstructures for fine-pitch RDL

Effects of electrolyte flow direction on height difference in electroplated Cu microstructures for fine-pitch RDL

Reducing Interface Resistance in Semiconductor System Through the Integration of Graphene

Analysis of Signal Transmission Efficiency in Semiconductor Interconnect and Proposal of Enhanced Structures

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