Protective properties of superhydrophobic coatings on copper and steel obtained by electrochemical method

Superhydrophobic coatings are obtained by cathodic deposition of copper or nickel on a copper plate with treatment with an ethanol solution of highest carboxylic acids with a long hydrocarbon radical simultaneously or sequentially. They are characterized by a contact angle of water wetting of the order of 155...160°.These coatings protect the copper substrate from corrosion in conditions of 100% humidity for 100...180 days, while maintaining the contact angle within 152…154°. There is no mass loss. The influence of the reversal of the current during electrolysis on the value of the contact angle of wetting is investigated. SEM images of superhydrophobic coatings are presented, indicating multilevel roughness. Superhydrophobic coating on carbon steel is obtained by cathodic deposition of nickel and subsequent surface treatment in an ethanol solution of myristic acid and annealing at 60° for two hours. The influence of the duration of electrolysis on the value of the contact angle of wetting is estimated. Its value is in the range of 151…154°. Exposure of a coated steel plate for 50 days in conditions of 100% humidity is characterized by the absence of weight loss and maintaining the contact angle up to 154°.

1. Wang, Y., Wang, W., Zhong, L., Wang, J., Jiang, Q., & Guo, X. (2010). Super-hydrophobic surface on pure magnesium substrate by wet chemical method. Appl. Surf.Sci., 256, 3837- 3840.

2. Kang, Z., Ye, Q., Sang, J., & Li, Y. (2009). Fabrication of super-hydrophobic surface on copper surface by polymer plating. J. Mater. Process.Technol., 209, 4543-4547.

3. Boinovich, L. B., Emelyanenko, K. A., Domantovsky, A. G., & Emelyanenko, A. M. (2018). Laser tailoring the surface chemistry and morphology for wear, scale and corrosion resistant superhydrophobic coatings. Langmuir, 34 (24), 7059-7066.

4. Xu, W., Shi, X., & Lu, S. (2011). Controlled growth of superhydrophobic films without any lowsurface-energy modification by chemical displacement on zinc substrates. Mater.Chem. Phys., 129, 1042-1046.

5. Khorsand, S., Raeissi, K., Ashrafizadeh, F., & Arenas, M. A. (2015). Relationship between the structure and water repellency of nickel–cobalt alloy coatings prepared by electrodeposition process. Surface&CoatingsTechnology, 276, 296-304.

6. Glukhov, V. G., Polyakov, N. A., Semiletov, A. M., & Kuznetsov, Yu. I. (2019). Obtaining superhydrophobic coatings on copper using electrochemical methods. Proceedings of the conference «Topical issues of electrochemistry, ecology and protection against corrosion», dedicated to the memory of Professor, Honored Worker of Science and Technology of the Russian Federation V.I. Vigdorovich, (23-25 Octob. 2019, Russia, Tambov), 392-394.

7. Chen, Z., Hao, L., Chen, A., Song, Q., & Chen, C. (2012). A rapid one-step process for fabrication of superhydrophobic surface by electrodeposition method. Electrochim. Acta, 59, 168-171.

8. Wang, P., Zhang, D., Qiu, R., & Wu, J. (2012). Superhydrophobic metal-complex film fabricated electrochemically on copper as a barrier to corrosive medium. Cor. Sci., 83, 317-326