| ArticleName |
Developing an immersion gold
process for surface finishing of printed circuit boards |
| ArticleAuthorData |
D. Mendeleev University of Chemical Technology of Russia, Moscow, Russia
E. V. Lopukhova, Undergraduate Student at the Department of Innovative Materials and Corrosion Protection, e-mail: lopoohova18@gmail.com
K. N. Smirnov, Associate Professor at the Department of Innovative Materials and Corrosion Protection, Candidate of Technical Sciences, e-mail: smirnov.k.n@muctr.ru
D. V. Mazurova, Associate Professor at the Department of Innovative Materials and Corrosion Protection, Candidate of Technical Sciences, e-mail: mazurova.d.v@muctr.ru
T. A. Vagramyan, Head of the Department of Innovative Materials and Corrosion Protection, Doctor of Technical Sciences, Professor, e-mail: vagramian.t.a@muctr.ru |
| Abstract |
An increasing number of devices that use printed circuit boards emphasizes the need to develop more efficient, cost-effective and reliable techniques for surface finishing of printed circuit boards. Immersion coatings are used as the top coat designed to protect conductor paths of printed circuit boards from oxidation and enable the soldering process. Due to its proneness to fast passivation, nickel is poorly solder weldable. Gold is known to protect this metal from oxidation. It dissolves in solder providing good flowability and hence solderability. Immersion gold is the most popular technique when it comes to manufacturing critical components as it ensures a combination of good solderability and surface flatness for mounting and soldering highly integrated components, which is a pre-requisite for modern items, with an increasing density of printed boards. Of acute importance today is the problem of developing an in-country immersion gold solution that could fully substitute all similar products made abroad. This paper looks at the immersion gold plating solution that contains potassium dicyanoaurate, a chelate-type ligand, a reducing agent and a buffering additive. The aim of this research is to understand how the immersion goldplating conditions influence the gold plating thickness and what would be the optimum parameters under which the deposited layer would meet the IPС-4552 standard. It was established that the introduction of the reducing agent to the immersion gold plating solution influences the plating thickness, with the process duration being rather long, and thus helps maintain the thickness of the finish while the concentration of gold in the solution drops. The paper demonstrates that the immersion gold plating solution can work in a stable mode for quite a long time. |
| References |
1. Chiminev A. Printed circuit board as the key component determining reliability of the final product. Electronics: Science, Technology, Business. 2020. No 6. pp. 42–47.
2. Kamarchuk A. V., Razzhivina K. R., Marchenko A. I., Bauman D. A. Analysis of wire bonding pull-off/shear force for various wire materials and contact pads. Reviews on Advanced Materials and Technologies. 2022. Vol. 4, No. 3. pp. 52–55.
3. Sato J., Kato M., Otani H., Homma T. et al. Substrate (Ni)-Catalyzed Electroless Gold Deposition from a Noncyanide Bath Containing Thiosulfate and Sulfite: Reaction Mechanism. Journal of the Electrochemical Society. 2002. Vol. 149, No. 3. pp. 164–167.
4. Tereshkin V., Grigorieva L., Kabin E. The electroless nickel/immersion gold surface finish of printed circuit boards. Issues and prospects. Part I. Tekhnologii v elektronnoy promyshlennosti. 2019. No. 5. pp. 38–41.
5. Lurie Ju. Ju. Handbook of analytical chemistry. 5th edition. Moscow : Khimiya, 1979. 480 p.
6. Nikolaeva E. Immersion gold plating: Questions and answers. Proizvodstvo elektroniki: tekhnologii, oborudovanie, materialy. 2007. No. 1. pp. 17–20.
7. Wang Y., Cao X., Wang W., Mitsuzak N. et al. Immersion gold deposition from a chloroauric acid–choline chloride solution: Deposition kinetics and coating performances. Surface and Coatings Technology. 2015. Vol. 265. pp. 62–67.
8. Won Y. S., Park S. S., Lee J., Kim J. Y. et al. The pH effect on black spots in surface finish: electroless nickel immersion gold. Journal of Applied Surface Science. 2010. Vol. 257, No. 1. pp. 56–61.
9. Chen M., Reid R. S. Solution speciation in the aqueous Na(I)–EDTA and K(I)-EDTA systems. Canadian Journal of Chemistry. 1993. Vol. 71. pp. 763–768.
10. Nowack B., Sigg L. Adsorption of EDTA and metal–EDTA complexes onto goethite. Journal of Colloid and Interface Science. 1996. Vol. 177, No. 1. pp. 106–121.
11. Accogli A., Gibertini E., Panzeri G., Lucotti A. et al. Understanding the failure mode of electroless nickel immersion gold process: in situ-raman spectroscopy and electrochemical characterization. Journal of the Electrochemical Society. 2020. Vol. 167, No. 8. 082507.
12. Hedwig G. R., Liddle J. R., Reeves R. D. Complex formation of nickel(II) ions with citric acid in aqueous solution: a potentiometric and spectroscopic study. Journal of Chemistry. 1980. Vol. 33, Iss. 8. pp. 1685–1693.
13. Zelenin O. Yu. Interaction of Ni2+ ion with citric acid in aqueous solution. Russian Journal of Coordination Chemistry. 2007. Vol. 33, No. 346. pp. 355–359.
14. Electroless gold plating liquid. IPC C23C18/44. Patent US20160040296A1. Applied: 22.12.14. Published: 11.02.16.
15. Lee D. J., Lee H. S. Major factors to the solder joint strength of ENIG layer in FC BGA package. Microelectronics Reliability. 2006. Vol. 46, No. 7. pp. 1119–1127.
16. Zotkin V. V., Zaytsev A. G., Gavrilin G. O., Arkhipov E. A. et al. Examining the process of electroless nickel plating as a stage of the ENIG process. Electroplating & Surface Treatment. 2015. Vol. 23, No. 1. pp. 47–51.
17. Shikhov S. Printed circuit board surface finishes: ENIG versus HASL. Tekhnologii v elektronnoy promyshlennosti. 2023. No. 1. pp. 12–13.
18. Wang Z., Gao J., Wang W. The impact of gold plating process for bonding pads on interconnection quality. IEEE Transactions on Device and Materials Reliability. 2022. Vol. 22, No. 1. pp. 65–72.
19. Pisarev A., Yafaeva P. Examining the ENIG finishes with medium and high concentrations of phosphorus. Tekhnologii v elektronnoy promyshlennosti. 2021. No. 2. pp. 29–31.
20. Tereshkin V., Grigorieva L., Kabin E. The Electroless nickel/immersion gold surface finish of printed circuit boards. Part II. Developing the KhimNiz 1600 technique at ELMA Centre. Tekhnologii v elektronnoy promyshlennosti. 2020. No. 4. pp. 10–14.
21. Seo W., Kim K. Ho., Kim Y. Ho., Yoo S. Effect of Ni-P plating temperature on growth of interfacial intermetallic compound in electroless nickel immersion gold/Sn-Ag-Cu solder joints. Journal of Electronic Materials. 2018. Vol. 47, No. 1. pp. 110–116.
22. IPC-TM-650. Test methods manual. 2021. 11 p.
23. GOST R 56427–2015. Soldering of electronic modules of radio-electronic means. Automated mixed and surface mounting using lead-free and conventional technologies. Technical requirements for the implementation of technological operations. Introduced: 01.09.2015. |
