Process development and bonding quality investigations of silicon layer stacking based on copper wafer bonding

被引:26
|
作者
Chen, KN [1 ]
Chang, SM [1 ]
Fan, A [1 ]
Tan, CS [1 ]
Shen, LC [1 ]
Reif, R [1 ]
机构
[1] MIT, Microsyst Technol Labs, Cambridge, MA 02139 USA
来源
APPLIED PHYSICS LETTERS | 2005年 / 87卷 / 03期
关键词
D O I
10.1063/1.1995943
中图分类号
O59 [应用物理学];
学科分类号
摘要
Process development of silicon layer stacking based on copper wafer bonding, grind-back, and etch-back was applied to demonstrate a strong four-layer-stack structure. Bonded copper layers in this structure became homogeneous layers and did not show original bonding interfaces. This process can be used in three-dimensional integrated circuit applications. Voids and total bonded area after each layer stacking were investigated for the bonding quality after each layer stacking. Large wafer bows from high residual stresses result in the structure failure at the stacking of a high number of layers. (c) 2005 American Institute of Physics.
引用
收藏
页数:3
相关论文
共 50 条
  • [41] SILICON-CARBIDE WAFER BONDING
    TONG, QY
    GOSELE, U
    YUAN, C
    STECKL, AJ
    REICHE, M
    JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1995, 142 (01) : 232 - 236
  • [42] Silicon waveguides produced by wafer bonding
    Poulsen, M
    Jensen, F
    Bunk, O
    Feidenhans'l, R
    Breiby, DW
    APPLIED PHYSICS LETTERS, 2005, 87 (26) : 1 - 3
  • [43] Silicon wafer bonding for MEMS manufacturing
    Mirza, AR
    Ayón, AA
    SOLID STATE TECHNOLOGY, 1999, 42 (08) : 73 - +
  • [44] Wafer bonding with intermediate parylene layer
    Shu, Qiong
    Huang, Xianju
    Wang, Ying
    Chen, Jing
    2008 9TH INTERNATIONAL CONFERENCE ON SOLID-STATE AND INTEGRATED-CIRCUIT TECHNOLOGY, VOLS 1-4, 2008, : 2420 - 2423
  • [45] Wafer Level Back to Back Hybrid Bonding for Multiple Wafer Stacking
    Li, H. Y.
    Kawano, M.
    Ji, L.
    Ji, H. M.
    Lim, C. S.
    2020 IEEE 22ND ELECTRONICS PACKAGING TECHNOLOGY CONFERENCE (EPTC), 2020, : 468 - 471
  • [46] Wafer bonding and layer splitting for microsystems
    Tong, QY
    Gösele, UM
    ADVANCED MATERIALS, 1999, 11 (17) : 1409 - 1425
  • [47] EBIC/PL investigations of dislocation network produced by silicon wafer direct bonding
    Jia, G.
    Seifert, W.
    Mchedlidze, T.
    Arguirov, T.
    Kittler, M.
    Wilhelm, T.
    Reiche, M.
    SUPERLATTICES AND MICROSTRUCTURES, 2009, 45 (4-5) : 314 - 320
  • [48] Die to Wafer Stacking with Low Temperature Hybrid Bonding
    Gao, Guilian
    Workman, Thomas
    Uzoh, Cyprian
    Bang, K. M.
    Mirkarimi, Laura
    Theil, Jeremy
    Suwito, Dominik
    Katkar, Rajesh
    Fountain, Gill
    Guevara, Gabe
    Lee, Bongsub
    2020 IEEE 70TH ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE (ECTC 2020), 2020, : 589 - 594
  • [49] Research on nano-thermocompression bonding process using nanoporous copper as bonding layer
    Li, Kecheng
    Liu, Xiaogang
    Chen, Mingxiang
    Liu, Sheng
    2014 15TH INTERNATIONAL CONFERENCE ON ELECTRONIC PACKAGING TECHNOLOGY (ICEPT), 2014, : 19 - 23
  • [50] 200 mm silicon wafer-to-wafer bonding with thin Ti layer under BEOL-compatible process conditions
    Yu, J
    McMahon, JJ
    Lu, JQ
    Gutmann, RJ
    SURFACE ENGINEERING 2004 - FUNDAMENTALS AND APPLICATIONS, 2005, 843 : 305 - 310
12345