Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding

Takafumi Fukushima; Taku Suzuki; Hideto Hashiguchi; Chisato Nagai; Jichoel Bea; Hiroyuki Hashimoto; Mariappan Murugesan; Kang Wook Lee; Tetsu Tanaka; Kazushi Asami; Yasuhiro Kitamura; Mitsumasa Koyanagi

doi:10.1109/3DIC.2015.7334578

Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding

Takafumi Fukushima, Taku Suzuki, Hideto Hashiguchi, Chisato Nagai, Jichoel Bea, Hiroyuki Hashimoto, Mariappan Murugesan, Kang Wook Lee, Tetsu Tanaka, Kazushi Asami, Yasuhiro Kitamura, Mitsumasa Koyanagi

研究成果: Conference contribution

1 被引用数 (Scopus)

抄録

Two types of high-throughput and high-precision multichip-to-wafer 3D stacking approaches are demonstrated: one is non-transfer stacking and the other one is transfer stacking. Both the stacking approaches employ a self-assembly technologies using liquid surface tension. In the former stacking scheme, large number of chips having 20-μm-square Cu/SnAg microbumps are directly self-assembled face-down on an interposer wafer, like flip-chip bonding. On the other hand, in the latter stacking scheme, the many chips having the microbumps are self-assembled face-up on a carrier wafer with bipolar electrodes for electrostatic chucking. Then, the latter chips are transferred from the carrier to another interposer in wafer-level processing. The alignment accuracies are evaluated and compared between the two stacking approaches. The resulting daisy chains show good electrical properties comparable to conventional flip-chip bonding.

本文言語	English
ホスト出版物のタイトル	2015 International 3D Systems Integration Conference, 3DIC 2015
出版社	Institute of Electrical and Electronics Engineers Inc.
ページ	TS7.4.1-TS7.4.4
ISBN（電子版）	9781467393850
DOI	https://doi.org/10.1109/3DIC.2015.7334578
出版ステータス	Published - 2015 11月 20
イベント	International 3D Systems Integration Conference, 3DIC 2015 - Sendai, Japan 継続期間: 2015 8月 31 → 2015 9月 2

出版物シリーズ

名前	2015 International 3D Systems Integration Conference, 3DIC 2015

Other

Other	International 3D Systems Integration Conference, 3DIC 2015
国/地域	Japan
City	Sendai
Period	15/8/31 → 15/9/2

ASJC Scopus subject areas

電子工学および電気工学

文献へのアクセス

10.1109/3DIC.2015.7334578

他のファイルとリンク

フィンガープリント

「Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding」の研究トピックを掘り下げます。これらがまとまってユニークなフィンガープリントを構成します。

引用スタイル

Fukushima, T., Suzuki, T., Hashiguchi, H., Nagai, C., Bea, J., Hashimoto, H., Murugesan, M., Lee, K. W., Tanaka, T., Asami, K., Kitamura, Y., & Koyanagi, M. (2015). Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding. In 2015 International 3D Systems Integration Conference, 3DIC 2015 (pp. TS7.4.1-TS7.4.4). [7334578] (2015 International 3D Systems Integration Conference, 3DIC 2015). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/3DIC.2015.7334578

Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding. / Fukushima, Takafumi; Suzuki, Taku; Hashiguchi, Hideto その他.

2015 International 3D Systems Integration Conference, 3DIC 2015. Institute of Electrical and Electronics Engineers Inc., 2015. p. TS7.4.1-TS7.4.4 7334578 (2015 International 3D Systems Integration Conference, 3DIC 2015).

研究成果: Conference contribution

Fukushima, T, Suzuki, T, Hashiguchi, H, Nagai, C, Bea, J, Hashimoto, H, Murugesan, M, Lee, KW, Tanaka, T, Asami, K, Kitamura, Y & Koyanagi, M 2015, Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding. in 2015 International 3D Systems Integration Conference, 3DIC 2015., 7334578, 2015 International 3D Systems Integration Conference, 3DIC 2015, Institute of Electrical and Electronics Engineers Inc., pp. TS7.4.1-TS7.4.4, International 3D Systems Integration Conference, 3DIC 2015, Sendai, Japan, 15/8/31. https://doi.org/10.1109/3DIC.2015.7334578

Fukushima T, Suzuki T, Hashiguchi H, Nagai C, Bea J, Hashimoto H その他. Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding. In 2015 International 3D Systems Integration Conference, 3DIC 2015. Institute of Electrical and Electronics Engineers Inc. 2015. p. TS7.4.1-TS7.4.4. 7334578. (2015 International 3D Systems Integration Conference, 3DIC 2015). doi: 10.1109/3DIC.2015.7334578

Fukushima, Takafumi ; Suzuki, Taku ; Hashiguchi, Hideto その他. / Transfer and non-transfer stacking technologies based on chip-to-wafer self-asembly for high-throughput and high-precision alignment and microbump bonding. 2015 International 3D Systems Integration Conference, 3DIC 2015. Institute of Electrical and Electronics Engineers Inc., 2015. pp. TS7.4.1-TS7.4.4 (2015 International 3D Systems Integration Conference, 3DIC 2015).

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abstract = "Two types of high-throughput and high-precision multichip-to-wafer 3D stacking approaches are demonstrated: one is non-transfer stacking and the other one is transfer stacking. Both the stacking approaches employ a self-assembly technologies using liquid surface tension. In the former stacking scheme, large number of chips having 20-μm-square Cu/SnAg microbumps are directly self-assembled face-down on an interposer wafer, like flip-chip bonding. On the other hand, in the latter stacking scheme, the many chips having the microbumps are self-assembled face-up on a carrier wafer with bipolar electrodes for electrostatic chucking. Then, the latter chips are transferred from the carrier to another interposer in wafer-level processing. The alignment accuracies are evaluated and compared between the two stacking approaches. The resulting daisy chains show good electrical properties comparable to conventional flip-chip bonding.",

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AU - Nagai, Chisato

AU - Bea, Jichoel

AU - Hashimoto, Hiroyuki

AU - Murugesan, Mariappan

AU - Lee, Kang Wook

AU - Tanaka, Tetsu

AU - Asami, Kazushi

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AB - Two types of high-throughput and high-precision multichip-to-wafer 3D stacking approaches are demonstrated: one is non-transfer stacking and the other one is transfer stacking. Both the stacking approaches employ a self-assembly technologies using liquid surface tension. In the former stacking scheme, large number of chips having 20-μm-square Cu/SnAg microbumps are directly self-assembled face-down on an interposer wafer, like flip-chip bonding. On the other hand, in the latter stacking scheme, the many chips having the microbumps are self-assembled face-up on a carrier wafer with bipolar electrodes for electrostatic chucking. Then, the latter chips are transferred from the carrier to another interposer in wafer-level processing. The alignment accuracies are evaluated and compared between the two stacking approaches. The resulting daisy chains show good electrical properties comparable to conventional flip-chip bonding.

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