Electrodeposition process of perrhenate ions from KNO3 and Na2SO4 background electrolytes in the presence of citric acid

Keywords: perrhenate ions, electrodeposition, rhenium, cyclic voltammetry, electrolysis

Abstract

Processes involved in the electrodeposition of perrhenate ions were studied from two different potassium nitrate and sodium sulfate background electrolytes in the presence of citric acid on graphite electrode by cyclic voltammetry method. Anodic and cathodic potentials of deposited film were determined. After electrolysis process, morphology and content of obtained deposited layers were investigated by SEM and X-Ray methods. The coated film from sodium sulfate background electrolyte was not uniform and Re content was 60.83-65.5%, in case of potassium nitrate electrolyte, the deposited film was more densely located, and Re content was 80.94-82.52%. In the presence of nickel sulfate and citric acid, an alloy was formed with content of Re 80.94-82.52%, 14.10-11.83% of Ni, 4.96-5.66% of impurities, which were confirmed by X-Ray method. The current density decreased with addition of citric acid into sodium sulfate background electrolyte and in cathodic area, the reduction potential of perrhenate ions remained the same, but oxidation potentials changed from 0.25 to 0.35 V and from 0.5 to 0.6 V. The influence of citric acid on potentials of the processes of reduction and oxidation of perrhenate ions from potassium nitrate gave following results: reduction peaks shifted from -0.35 to -0.55 V, and multi peaks of oxidation appeared which were not noticeable without citric acid. It was shown that citric acid has inhibitory effect on reduction and oxidation of perrhenate ions. It is shown that the electrochemical reduction of perrhenate ions leads to the formation of rhenium dioxide in different forms.

References

1 Uscategui AV, Mosquera E, Cifuentes L (2013) Mater Lett 94:44-46. Crossref

2 Naumov AV (2008) Russ J Non-Ferrous Met 48:418-423. Crossref

3 Polyak DE (2011) Rhenium [Advance Release].

4 Casas JM, Sepúlveda E, Bravo L, Cifuentes L (2011) Hydrometallurgy 113-114:192-194. Crossref

5 Cao H, Chai D, Wu L, Zheng G (2017) J Electrochem Soc 164:D825-D827. Crossref

6 Veerakumar P, Rajkumar C, Chen SM, Thirumalraj B, Lin KC (2018) Electrochim Acta 271:433-447. Crossref

7 Zhulikov V V., Gamburg YD (2016) Russ J Electrochem 52:847-857. Crossref

8 Ni JQ, Han KQ, Yu MH, Zhang CY (2018) Mater Sci Forum 913:445-450. Crossref

9 Li C, Li X, Wang Z, Guo H (2015) Rare Met Mater Eng 44:1561-1567. Crossref

10 Dolmatov VY, Rudenko D V., Burkat GK, Aleksandrova AS, Vul’ AY, Aleksenskii AE, et al. (2019) J Superhard Mater 41:169-177. Crossref

11 Kazimierczak H, Szymkiewicz K, Rogal Ł, Gileadi E, Eliaz N (2018) J Electrochem Soc 165:D526-D535. Crossref

12 Belevskii SS, Gotelyak A V., Yushchenko SP, Dikusar AI (2019) Surf Eng Appl Electrochem 55:119-129. Crossref

13 Kuznetsov VV, Golyanin KE, Ladygina YS, Pshenichkina TV, Lyakhov BF, Pokholok KV (2015) Russ J Electrochem 51:748-757. Crossref

14 Benaicha M, Allam M, Dakhouche A, Hamla M (2016) Int J Electrochem Sci 11:7605-7620. Crossref

15 Ye T, Institute of Microelectronics of Chinese Academy of Sciences, IEEE Electronics Packaging Society, Zhongguo dian zi xue hui. Electronics Manufacturing & Packaging Technology Society, Fu dan da xue (Shanghai C, Institute of Electrical and Electronics Engineers Di shi ba jie dian zi feng zhuang ji shu guo ji hui yi = the 19th International Conference on Electronic Packaging Technology : August 8-11, Shanghai, China. ISBN 9781538663868

16 Bersirova OL, Kublanovsky VS (2019) Mater Sci 54:506-511. Crossref

17 Yapontseva YS, Kublanovsky VS, Vyshnevskyi OA (2018) J Alloy Comp 766:894-901. Crossref

18 Hahn BP, May RA, Stevenson KJ (2007) Langmuir 23:10837-10845. Crossref

19 Méndez E, Cerdá MF, Castro Luna AM, Zinola CF, Kremer C, Martins ME (2003) J Colloid Interface Sci 263:119-132. Crossref

20 Salakhova E, Majidzade V, Novruzova F, Kalantarova P, Huseynova R (2012) J Chem Chem Eng 6:489-494.

21 Vargas-Uscategui A, Mosquera E, Chornik B, Cifuentes L (2015) Electrochim Acta 178:739-747. Crossref

22 Cao H, Chai D, Wu L, Zheng G (2017) J Electrochem Soc 164:D825-D827. Crossref

23 Huang Q, Hu Y (2018) J Electrochem Soc 165:D796-D801. Crossref

24 Elgrishi N, Rountree KJ, McCarthy BD, Rountree ES, Eisenhart TT, Dempsey JL (2018) J Chem Educ 95:197-206. Crossref

25 Naor A, Eliaz N, Gileadi E (2009) Electrochim Acta 54:6028-6035. Crossref
Published
2020-03-25
How to Cite
Zhumasheva, N., Kudreeva, L., Kalyyeva, A., & Badavamova, G. (2020). Electrodeposition process of perrhenate ions from KNO3 and Na2SO4 background electrolytes in the presence of citric acid. Chemical Bulletin of Kazakh National University, 96(1), 4-12. https://doi.org/https://doi.org/10.15328/cb1087

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