Microstructure and growth of Cu hillock on redistribution line under electromigration

Yen Cheng Huang; Min Yan Tsai; Ting Chun Lin; Yung Sheng Lin; Chi Pin Hung; Kwang Lung Lin

doi:10.1007/s10854-024-12407-9

Microstructure and growth of Cu hillock on redistribution line under electromigration

Yen Cheng Huang
, Min Yan Tsai
, Ting Chun Lin
, Yung Sheng Lin
, Chi Pin Hung
, Kwang Lung Lin

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

The formation of hillock at the anode side of a circuit under electromigration is detrimental to electrical performance and electronic reliability. The study presented a detailed investigation of the microstructure of Cu hillock formed on 2 μm x 3 μm Cu redistribution line under high electrical current density 1.44 × 10⁷ A/cm². The electron backscatter diffraction analysis revealed that the microstructure of the Cu redistribution line remain intact after 162 min current stressing. High-resolution transmission electron microscope analysis showed that the dome shape Cu hillock formed is polycrystalline with amorphous inclusion and twin structure. A mechanism considering radial surface diffusion of Cu atoms was proposed to illustrate the growth of dome shape Cu hillock under electromigration.

Original language	English
Article number	659
Journal	Journal of Materials Science: Materials in Electronics
Volume	35
Issue number	9
DOIs	https://doi.org/10.1007/s10854-024-12407-9
Publication status	Published - 2024 Mar

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Condensed Matter Physics
Electrical and Electronic Engineering

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10.1007/s10854-024-12407-9

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title = "Microstructure and growth of Cu hillock on redistribution line under electromigration",

abstract = "The formation of hillock at the anode side of a circuit under electromigration is detrimental to electrical performance and electronic reliability. The study presented a detailed investigation of the microstructure of Cu hillock formed on 2 μm x 3 μm Cu redistribution line under high electrical current density 1.44 × 107 A/cm2. The electron backscatter diffraction analysis revealed that the microstructure of the Cu redistribution line remain intact after 162 min current stressing. High-resolution transmission electron microscope analysis showed that the dome shape Cu hillock formed is polycrystalline with amorphous inclusion and twin structure. A mechanism considering radial surface diffusion of Cu atoms was proposed to illustrate the growth of dome shape Cu hillock under electromigration.",

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AU - Huang, Yen Cheng

AU - Tsai, Min Yan

AU - Lin, Ting Chun

AU - Lin, Yung Sheng

AU - Hung, Chi Pin

AU - Lin, Kwang Lung

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2024.

PY - 2024/3

Y1 - 2024/3

N2 - The formation of hillock at the anode side of a circuit under electromigration is detrimental to electrical performance and electronic reliability. The study presented a detailed investigation of the microstructure of Cu hillock formed on 2 μm x 3 μm Cu redistribution line under high electrical current density 1.44 × 107 A/cm2. The electron backscatter diffraction analysis revealed that the microstructure of the Cu redistribution line remain intact after 162 min current stressing. High-resolution transmission electron microscope analysis showed that the dome shape Cu hillock formed is polycrystalline with amorphous inclusion and twin structure. A mechanism considering radial surface diffusion of Cu atoms was proposed to illustrate the growth of dome shape Cu hillock under electromigration.

AB - The formation of hillock at the anode side of a circuit under electromigration is detrimental to electrical performance and electronic reliability. The study presented a detailed investigation of the microstructure of Cu hillock formed on 2 μm x 3 μm Cu redistribution line under high electrical current density 1.44 × 107 A/cm2. The electron backscatter diffraction analysis revealed that the microstructure of the Cu redistribution line remain intact after 162 min current stressing. High-resolution transmission electron microscope analysis showed that the dome shape Cu hillock formed is polycrystalline with amorphous inclusion and twin structure. A mechanism considering radial surface diffusion of Cu atoms was proposed to illustrate the growth of dome shape Cu hillock under electromigration.

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ER -

Microstructure and growth of Cu hillock on redistribution line under electromigration

Abstract

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