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

页码：76 / 84

页数：9

共 50 条

[21] Incorporation of hydrogen in carbon-tungsten co-deposition layers formed by hydrogen plasma sputtering
Katayama, K.
Okamura, T.
Imaoka, K.
Sasaki, M.
Uchida, Y.
Nishikawa, M.
Fukada, S.
FUSION SCIENCE AND TECHNOLOGY, 2007, 52 (03) : 640 - 644
[22] Hydrogen retention in carbon-tungsten co-deposition layer formed by hydrogen RF plasma
Katayama, K
Kawasaki, T
Manabe, Y
Nagase, H
Takeishi, T
Nishikawa, M
THIN SOLID FILMS, 2006, 506 : 188 - 191
[23] Morphology and internal structure of copper deposits electrodeposited by the pulsating current regime in the hydrogen co-deposition range
Nikolic, Nebojsa D.
Brankovic, Goran
Maksimovic, Vesna M.
JOURNAL OF SOLID STATE ELECTROCHEMISTRY, 2012, 16 (01) : 321 - 328
[24] Morphology and internal structure of copper deposits electrodeposited by the pulsating current regime in the hydrogen co-deposition range
Nebojša D. Nikolić
Goran Branković
Vesna M. Maksimović
Journal of Solid State Electrochemistry, 2012, 16 : 321 - 328
[25] Hydrogen Embrittlement Suppressors for Nickel-Free Electroless Copper Baths
Bernhard, Tobias
Bremmert, Stefanie Manuela
Dieter, Sascha
Gregoriades, Laurence John
Steinhauser, Edith
2022 17TH INTERNATIONAL MICROSYSTEMS, PACKAGING, ASSEMBLY AND CIRCUITS TECHNOLOGY CONFERENCE (IMPACT), 2022,
[26] Investigation of Ni-YSZ SOFC anode fabricated via electroless nickel co-deposition
Baba, Nor Bahiyah
Davidson, Alan
PEEA 2011, 2011, 23
[27] Stabilizing Nickel-Copper Co-Deposition Electrochromism with the Assistance of Bromine Redox
Liu, Xiangyu
Li, Menghan
Sun, Xujing
Yu, Zehao
Meng, Fengjiao
Liu, Xuan
Guo, Tan
Du, Lingyu
Kang, Litao
INORGANIC CHEMISTRY, 2025, 64 (02) : 1016 - 1022
[28] Formation of homogenous copper film on MWCNTs by an efficient electroless deposition process
Sahraei, Abolfazl Alizadeh
Saeed, Hamidreza Naser
Fathi, Alireza
Baniassadi, Majid
Afrookhteh, Sepehr Sima
Givi, Mohammad Kazem Besharati
SCIENCE AND ENGINEERING OF COMPOSITE MATERIALS, 2017, 24 (03) : 345 - 352
[29] Co-deposition and thermal conductivity of nickel–graphene composite coatings on copper surface
Yang Lingling
Zhu Yanjie
Liu Haokai
Guo Tao
Tang Hui
Ya Shuangdong
Li Yu
Wang Hongguang
Luo Yanli
Ma Jiuming
Wan Dong
Applied Physics A, 2023, 129
[30] The effect of hydrogen co-deposition on the morphology of copper electrodeposits. II. Correlation between the properties of electrolytic solutions and the quantity of evolved hydrogen
Nikolic, N. D.
Brankovic, G.
Pavlovic, M. G.
Popov, K. I.
JOURNAL OF ELECTROANALYTICAL CHEMISTRY, 2008, 621 (01) : 13 - 21

← 1 2 3 4 5 →