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Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation

Underfill process is a critical manufacturing process to safeguard and enhance the package reliability of flip-chip devices. In most underfill researches, the underfill flow was primarily investigated through numerical simulation. Nonetheless, the numerical simulation required a tremendously long ti...

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Main Authors: Ng F.C., Zawawi M.H., Tung L.H., Abas M.A., Abdullah M.Z.
Other Authors: 57192101900
Format: Article
Published: Penerbit Akademia Baru 2023
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spelling my.uniten.dspace-256832023-05-29T16:12:42Z Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation Ng F.C. Zawawi M.H. Tung L.H. Abas M.A. Abdullah M.Z. 57192101900 39162217600 57210387852 56893346700 31567537400 Underfill process is a critical manufacturing process to safeguard and enhance the package reliability of flip-chip devices. In most underfill researches, the underfill flow was primarily investigated through numerical simulation. Nonetheless, the numerical simulation required a tremendously long time to complete. This paper presents a new symmetrical unit-cell approach to simulate the flip-chip underfill encapsulation process. The current numerical simulation is based on the finite volume method scheme. By exploiting the repetitive symmetry of bump array in flip-chip, the computational domain was simplified into a long array of unit-cells of one-pitch thick while the symmetrical walls between adjacent unit-cells were modelled using the periodic boundary condition. Accordingly, the computational costs can be greatly reduced. Alongside with the introduction of a new numerical approach of flip-chip underfill, the variation effect of bump pitch was studied by considering four flip-chip cases with bump pitches ranging from 0.08 mm to 0.16 mm. The numerical findings were found to in great consensus to the referencing experimental data, with the discrepancy, not more than 14.54%. Additional validation with the analytical filling time model revealed that both the numerical and analytical filling progressions are comparable. It is found that the increases in bump pitch can reduce the filling time at a particular filling distance, such that the filling time was halved within the investigated range of bump pitch. This new numerical approach is particularly useful for the simulation works of underfill process, especially the design and process optimization. � 2020 PENERBIT AKADEMIA BARU-All rights reserved. Final 2023-05-29T08:12:42Z 2023-05-29T08:12:42Z 2020 Article 10.37934/cfdl.12.8.5563 2-s2.0-85090221766 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85090221766&doi=10.37934%2fcfdl.12.8.5563&partnerID=40&md5=b2c289fcdfb03cdd8b7a8d53abe956fc https://irepository.uniten.edu.my/handle/123456789/25683 12 8 55 63 All Open Access, Bronze Penerbit Akademia Baru Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
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continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
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description Underfill process is a critical manufacturing process to safeguard and enhance the package reliability of flip-chip devices. In most underfill researches, the underfill flow was primarily investigated through numerical simulation. Nonetheless, the numerical simulation required a tremendously long time to complete. This paper presents a new symmetrical unit-cell approach to simulate the flip-chip underfill encapsulation process. The current numerical simulation is based on the finite volume method scheme. By exploiting the repetitive symmetry of bump array in flip-chip, the computational domain was simplified into a long array of unit-cells of one-pitch thick while the symmetrical walls between adjacent unit-cells were modelled using the periodic boundary condition. Accordingly, the computational costs can be greatly reduced. Alongside with the introduction of a new numerical approach of flip-chip underfill, the variation effect of bump pitch was studied by considering four flip-chip cases with bump pitches ranging from 0.08 mm to 0.16 mm. The numerical findings were found to in great consensus to the referencing experimental data, with the discrepancy, not more than 14.54%. Additional validation with the analytical filling time model revealed that both the numerical and analytical filling progressions are comparable. It is found that the increases in bump pitch can reduce the filling time at a particular filling distance, such that the filling time was halved within the investigated range of bump pitch. This new numerical approach is particularly useful for the simulation works of underfill process, especially the design and process optimization. � 2020 PENERBIT AKADEMIA BARU-All rights reserved.
author2 57192101900
author_facet 57192101900
Ng F.C.
Zawawi M.H.
Tung L.H.
Abas M.A.
Abdullah M.Z.
format Article
author Ng F.C.
Zawawi M.H.
Tung L.H.
Abas M.A.
Abdullah M.Z.
spellingShingle Ng F.C.
Zawawi M.H.
Tung L.H.
Abas M.A.
Abdullah M.Z.
Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
author_sort Ng F.C.
title Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
title_short Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
title_full Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
title_fullStr Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
title_full_unstemmed Symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
title_sort symmetrical unit-cell numerical approach for flip-chip underfill flow simulation
publisher Penerbit Akademia Baru
publishDate 2023
_version_ 1806426381655998464
score 13.188404

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