Nickel dependence of hydrogen generation, hydrogen co-deposition and film stress in an electroless copper process

被引:16
|
作者
Sharma, Tanu [1 ]
Landry, Alexandre E. [1 ]
Leger, Alexandre [1 ]
Brown, Delilah A. [1 ]
Bernhard, Tobias [2 ]
Zarwell, Sebastian [2 ]
Bruening, Frank [2 ]
Bruning, Ralf [1 ]
机构
[1] Mt Allison Univ, Phys Dept, 67 York St, Sackville, NB E4L 1E6, Canada
[2] Atotech Deutschland GmbH, Erasmusstr 20, D-10553 Berlin, Germany
来源
THIN SOLID FILMS | 2018年 / 666卷
关键词
Electroless plating; Copper; Hydrogen content; Mixed potential; Voids; Stress; DUCTILITY; MECHANISM; DEPOSITS; FORMALDEHYDE; EVOLUTION; HYDRIDE; STRAIN; CU;
D O I
10.1016/j.tsf.2018.09.029
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Hydrogen co-deposition in electroless copper is a cause of embrittlement, voids and blisters. Hydrogen release in the plating bath and its incorporation into the copper films were measured. The amount of hydrogen in the films was determined by monitoring its release over several days at ambient conditions. The mixed potential and the film stress were recorded during film deposition. Adding nickel ions in the plating bath lowers the mixed potential, and it reduces hydrogen incorporation from about 25 at.% to 0.01 at.%. However, the total amount of hydrogen generated per amount of plated copper remains unchanged. For films plated without nickel, the biaxial stress of the films and their hydrogen content are proportional with 3.2 +/- 0.3 MPa/at. % H.
引用
收藏
页码:76 / 84
页数:9
相关论文
共 50 条
  • [1] Temperature dependence of hydrogen co-deposition with metals
    Gasparyan, Yury
    Krat, Stepan
    Davletiyarova, Aibope
    Vasina, Yana
    Pisarev, Alexander
    FUSION ENGINEERING AND DESIGN, 2019, 146 : 1043 - 1046
  • [2] Particles co-deposition by electroless nickel
    Apachitei, I
    Duszczyk, J
    Katgerman, L
    Overkamp, PJB
    SCRIPTA MATERIALIA, 1998, 38 (09) : 1383 - 1389
  • [3] Nickel dependence of hydrogen co-deposition and nanoporosity in electrolessly deposited Cu-films
    Bernhard, Tobias
    Steinhauser, Edith
    Kempa, Stefan
    Krilles, Gerson
    Massey, Roger
    Bruning, Frank
    2020 IEEE 70TH ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE (ECTC 2020), 2020, : 735 - 741
  • [4] Co-deposition of luminescent particles with electroless nickel
    Das, CM
    Grover, AK
    Suri, AK
    TRANSACTIONS OF THE INSTITUTE OF METAL FINISHING, 2002, 80 : 128 - 131
  • [5] Palladium-ruthenium membranes for hydrogen separation fabricated by electroless co-deposition
    Gade, Sabina K.
    Keeling, Matthew K.
    Davidson, Alexander P.
    Hatlevik, Oyuind
    Way, J. Douglas
    INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2009, 34 (15) : 6484 - 6491
  • [6] High hydrogen permeability of Pd-Ru-In membranes prepared by electroless co-deposition
    Chen, Zihui
    Yang, Zhanbing
    Tong, Yujin
    Yin, Zhaohui
    Li, Shuai
    SEPARATION AND PURIFICATION TECHNOLOGY, 2024, 343
  • [7] High hydrogen permeability of Pd-Ru-In membranes prepared by electroless co-deposition
    Chen, Zihui
    Yang, Zhanbing
    Tong, Yujin
    Yin, Zhaohui
    Li, Shuai
    Separation and Purification Technology, 2024, 343
  • [8] Preparation of hydrogen-permselective palladium-silver alloy composite membranes by electroless co-deposition
    Huang, TC
    Wei, MC
    Chen, HI
    SEPARATION AND PURIFICATION TECHNOLOGY, 2003, 32 (1-3) : 239 - 245
  • [9] Application of pulsating overpotential regime on the formation of copper deposits in the range of hydrogen co-deposition
    N. D. Nikolić
    G. Branković
    V. M. Maksimović
    M. G. Pavlović
    K. I. Popov
    Journal of Solid State Electrochemistry, 2010, 14 : 331 - 338
  • [10] Application of pulsating overpotential regime on the formation of copper deposits in the range of hydrogen co-deposition
    Nikolic, N. D.
    Brankovic, G.
    Maksimovic, V. M.
    Pavlovic, M. G.
    Popov, K. I.
    JOURNAL OF SOLID STATE ELECTROCHEMISTRY, 2010, 14 (02) : 331 - 338
12345