Changer in the texture orientation of electrolytic nickel by cold air plasma

The effects of cold air plasma influence on the change in the microstructure, stress state and texture of the cathode nickel brand H-1 were studied. By the method of target metallography it has been established that the microstructure does not change under exposure to the cold air plasma. A decrease in the level of micro- and macrostress is shown. By the method of inverse pole figures it has been established that the pole density of the orientations (111), (200) and (311) decreases when exposed to plasma; orientation (311) changes the least intensively. The pole density of the orientation (220) increases from 4.42 in the initial state to 13.3 after plasma treatment, which means an increase in the electrolytic deposition texture. The causes of the observed effects are being discussed. It is assumed that the changes introduced by the plasma occur at a scale level that is much smaller than the size of the coherent scatter blocks.

1. Vivet L., Joudrier A.-L., Bouttemy M., Vigneron J., and oth. Wettability and XPS-analyses of nickel–phosphorus surfaces after plasma treatment: an efficient approach for surface qualification in mechatronic processes. Applied Surface Science. 2013, no. 274, pp.71–78.

2. Shuang Dong, Peng Guo, Yue Chen, Gui-yun Chen, and oth. Surface modification via atmospheric cold plasma (ACP): Improved functional properties and characterization of zein film. Industrial Crops and Products, 2018, V. 115, pp. 124-133.

3. Zendehnam Arman, Ghasemi Javad, Zendehnam Akbar. Employing cold atmospheric plasma (Ar, He) on Ag thin film and their influences on surface morphology and anti-bacterial activity of silver films for water treatment. International Nano Letters, 2018, no.8, pp.157–164.

4. Prysiazhnyi V., Stupavská M., Ráhe J., Kleber C., and oth. A comparison of chemical and atmospheric plasma assisted copper plating on carbon fiber reinforced epoxy polymer surfaces. Surface & Coatings Technology. 2014, no.258, pp.1082–1089.

5. Tereshko I.V., Abidzina V.V., Elkin I.E. The formation of nanoclusters in metals by the low-energy ion irradiation Surface and Coatings Technology, 2007, vol. 201, pp. 8552–8556.

6. Tereshko I. V., Abidzina V. V., Elkin I. E., Tereshko A. M. Nanostructural evolution of steel and titanium alloys exposed to glow discharge – Nuclear Instruments and Methods in Physics Research. Section B: Beam Interactions with Materials and Atoms, 2007, vol. 261, pp. 678–681.

7. Anisovich A. G., Azharonok V. V., Gologan V. F., Bobanova Zh. I. and oth. The Effect of Low Temperature Nonequilibrium Air Plasma on the Structure and Properties of Copper and Chromium Electrodeposited Coatings. International Journal of Research Studies in Science, Engineering and technology, 2016, no.2, pp.42-49.

8. Anisovich A. G., Azharonok V. V., .Gologan V. F., Tereshko I. V. Surface transformation of electrodeposited coatings under exposure to cold plasma and magnetic field. Abstracts of 7th International Conference on “Materials science and Condensed Matter Physics’, Chisinau, 2014, 281 p.

9. Barvinok V. A., Rjasnyj A. V. Vlijanie nizkojenergeticheskoj plazmennoj obrabotki na fiziko-mehanicheskie svojstva i strukturu aljuminija i ego splavov [The effect of low-energy plasma processing on the physicomechanical properties and structure of aluminum and its alloys] . Vestnik Samarskogo gosudarstvennogo tehnicheskogo universiteta = Bulletin of Samara State Technical University, 2009, no.2. Vol. 19, pp. 193–199.

10. Anisovich A. G., Azharonok V. V., Filatova I. I. Lattice strain as a factor of structure formation. Abstracts of 8th International Conference on “Materials science and Condensed Matter Physics’, Chisinau, 2016. p. 327.

11. Logvin V. A. , Zholobov A. A. , Logvina E. V. Rezhushhaja chast’ instrumenta [Tool cutting]. Patent RB, , no. 7492, 2011.

12. Logvin V. A., Logvina E. V. Sposob obrabotki izdelija v vakuume [The method of processing the product in vacuum] . Patent RB, no. 16595, 2012.

13. Logvin V. A., Logvina E. V. Sposob poverhnostnoj obrabotki izdelija v vakuume i ustrojstvo dlja ego osushhestvlenija [The method of surface treatment of the product in vacuum and a device for its implementation]. Patent RB, no. 16343, 2012.

14. Anisovich A. G., Azharonok V. V., Basalaj A. V., Goncharik S. V. Strukturnye izmenenija v mednyh splavah pod vozdejstviem holodnoj plazmy vozduha [Structural changes in copper alloys under the influence of cold air plasma]. «Physics and diagnostics of laboratory and astrophysical plasmas». The XI Belarusian-Serbian symposium Minsk, 2016, pp. 34–37.

15. Azharonok V. V., Anisovich A. G., Basalaj A. V., Goncharik S. V. Transformacija struktury medi pod vozdejstviem neravnovesnoj nizkotemperaturnoj plazmy vozduha [Transformation of the copper structure under the influence of a nonequilibrium lowtemperature air plasma]. Inzhenerno-fizicheskij zhurnal = Engineering Physics Journal, 2013, no. 4, pp. 731–738.

16. Gogishvili O. Sh., Kononov G. G., Lavrinenko I. P., Ladykin S. P. K metodike postroenija obratnyh poljusnyh figure [To the technique of constructing inverse pole figures]. Zavodskaja laboratorija = Factory laboratory, 1981, no.7, pp. 32–34.

17. Lajner D. I., Radishevskij A. I., Komarova I. A. Sposob postroenija normirovannyh obratnyh poljusnyh figure [A method of constructing normalized inverse pole figures]. Kristallografija = Crystallography, 1974, Vol. 19, no.5, pp. 942–945.

18. Gorelik S. S., Rastorguev L. N., Skakov Ju. A. Rentgenograficheskij i jelektronnoopticheskij analiz [Radiographic and electron-optical analysis]. Moscow, Metallurgija Publ., 1970, 366 p.

19. Vasserman G, Greven I. Tekstury metallicheskih materialov [Textures of metal materials]. Moscow, Metallurgija Publ., 1969, 655 p.