- PII
- 10.31857/S0424857024080013-1
- DOI
- 10.31857/S0424857024080013
- Publication type
- Article
- Status
- Published
- Authors
- Volume/ Edition
- Volume 60 / Issue number 8
- Pages
- 530-538
- Abstract
- The possibility of targeted electrodeposition of coatings in the lead-bismuth binary system is discussed. The analysis of metal content in electrodeposits was performed using square-wave stripping voltammetry of solutions simultaneously containing lead and bismuth. The obtained results were supported by scanning electron microscopy, energy-dispersive X-ray spectroscopy, and powder X-ray diffraction analysis. The electrodeposition conditions of obtaining Pb7Bi3 ε-phase, which is promising for the application in superconducting microelectronics, were found.
- Keywords
- свинец висмут квадратно-волновая инверсионная вольтамперометрия электроосаждение
- Date of publication
- 15.08.2024
- Year of publication
- 2024
- Number of purchasers
- 0
- Views
- 40
References
- 1. Niwata, M., Masutomi, R., and Okamoto, T., Magnetic-field-induced superconductivity in ultrathin Pb films with magnetic impurities, Phys. Rev. Lett., 2017, vol. 119, p. 257001.
- 2. Nguyen, T.D., Frydman, A., and Bourgeois, O., Investigation of specific heat in ultrathin two-dimensional superconducting Pb, Phys. Rev. B, 2020, vol. 101, p. 014509.
- 3. Pinheiro, L.B.L.G., Jiang, L., Abbey, E.A., Chaves, Davi A.D., Chiquito, A.J., Johansen, T.H., Van de Vondel, J., Xue, C., Zhou, Y.-H., Silhanek, A.V., Ortiz, W.A., and Motta, M., Magnetic flux penetration in nanoscale wedge-shaped superconducting thin films, Phys. Rev. B, 2022, vol. 106, p. 224520.
- 4. Zhang, A.-L., Jiang, W.-Y., Chen, X.-H., Zhang, X.-K., Lu, W.-L., Chen, F., Feng, Z.-J., Cao, S.-X., Zhang, J.-C., and Ge, J.-Y., Anomalous magnetization jumps in granular Pb superconducting films, Curr. Appl. Phys., 2022, vol. 35, p. 32.
- 5. Paul, S., Biswas, S., and Gupta, A.K., Micron size superconducting quantum interference devices of lead (Pb), Supercond. Sci. Technol., 2017, vol. 30, p. 025017.
- 6. Nuclear Energy Agency (2015), Handbook on lead-bismuth eutectic alloy and lead properties, materials compatibility, thermal-hydraulics and technologies, Paris: OECD Publishing, 2015. 949 p.
- 7. Gokcen, N.A., The Bi-Pb (bismuth-lead) system, J. Phase Equilibria, 1992, vol 13, p. 21.
- 8. Rasmussen, S.E. and Lundtoft, B., Crystal data for Pb7Bi3, a superconducting ε-phase in the Pb–Bi system, Powder Diffr., 1987, vol. 2, p. 28.
- 9. Evetts, J.E. and Wade, J.M.A., Superconducting properties and the phase diagrams of the Pb–Bi and Pb-In alloy systems, J. Phys. Chem. Solids, 1970, vol. 31, p. 973.
- 10. Gandhi, A.C., Chan, T.S., and Wu, S.Y., Phase diagram of PbBi alloys: structure-property relations and the superconducting coupling, Supercond. Sci. Technol., 2017, vol. 30, p. 105010.
- 11. Chang, M S., Mohd Salleh, M.A.A., and Halin, D.S.C., A short review: properties of superconducting solder, IOP Conf. Ser.: Mater. Sci. Eng., 2020, vol. 957, p. 012059.
- 12. Huang, H.-C.W. and Gilbert, B.L., Preparation of Pb–Bi film by alloy evaporation I: film composition control, Thin Solid Films, 1982, vol. 91, p. 201.
- 13. Li, P., Xie, K., Li, L., Li, X., Xia, Y., Zhang, R., and Qin, S., Epitaxial growth of one-monolayer Pb1−xBix alloy films, Phys. Status Solidi B, 2022, vol. 259, p. 2200095.
- 14. Strukov, G.V., Stolyarov, V.S., Strukova, G.K., and Zverev, V.N., The superconducting properties of nanostructured Pb7Bi3 films obtained by pulse electroplating, Physica C, 2012, vol. 483, p. 162.
- 15. Wang, X.-W., He, Z.-C., Li, J.-S., and Yuan, Z.-H., A facile method of fabricating PbBi alloy nanowires with controlled component proportion, J. Alloys Compd., 2014, vol. 595, p. 221.
- 16. Давыдов, А.Д., Волгин, В.М. Электрохимическое локальное безмасковое микро/нано размерное осаждение, растворение и оксидирование металлов и полупроводников (обзор). Электрохимия. 2020. Т. 56. С. 56. [Davydov, A.D. and Volgin, V.M., Electrochemical local maskless micro/nanoscale deposition, dissolution, and oxidation of metals and semiconductors (a review), Russ. J. Eleсtrochem., 2020, vol. 56, p. 52.]
- 17. Goncharova, A.S., Napolskii, K.S., Skryabina, O.V., Stolyarov, V.S., Levin, E.E., Egorov, S.V., Eliseev, A.A., Kasumov, Yu.A., Ryazanov, V.V., and Tsirlina, G.A., Bismuth nanowires: electrochemical fabrication, structural features, and transport properties, Phys. Chem. Chem. Phys., 2020, vol. 22, p. 14953.
- 18. Леонтьев, А.П., Напольский, К.С. Численное моделирование вольтамперограмм и хроноамперограмм для модифицированного пористой пленкой электрода. Электрохимия. 2022. Т. 58. С. 508. [Leontiev, A.P. and Napolskii, K.S., Numerical simulation of chronoamperograms and voltammograms for electrode modified with nanoporous film, Russ. J. Eleсtrochem., 2022, vol. 58, p. 741.]
- 19. Бограчев, Д.А., Кабанова, Т.Б., Давыдов, А.Д. Анализ влияния концентрационной зависимости тока обмена на электроосаждение металла в нанопорах темплата. Электрохимия. 2023. Т. 59. С. 501. [Bograchev, D.A., Kabanova, T.B., and Davydov A.D., Analysis of effect of concentration dependence of exchange current on metal electrodeposition into template nanopores, Russ. J. Eleсtrochem., 2023, vol. 59, p. 651.]
- 20. Ноян, А.А., Колесник, И.В., Леонтьев, А.П., Напольский, К.С. Электрокристаллизация металлов в каналах пористых пленок анодного оксида алюминия: реальная структура темплата и количественная модель электроосаждения. Электрохимия. 2023. Т. 59. С. 378. [Noyan, A.A., Kolesnik, I.V., Leontiev, A.P., and Napolskii, K.S., Electrocrystallization of metals in channels of porous films of anodic aluminum oxide: The real template structure and the quantitative model of electrodeposition, Russ. J. Eleсtrochem., 2023, vol. 59, p. 489.]
- 21. Волгин, В.М., Кабанова, Т.Б., Гнидина, И.В., Давыдов, А.Д. Моделирование формирования металлических микроструктур локальным электроосаждением на электропроводной подложке. Электрохимия. 2023. Т. 59. С. 483. [Volgin, V.M., Kabanova, T.B., Gnidina, I.V., and Davydov, A.D., Modeling of the metal microstructure formation by local electrodeposition onto conducting substrates, Russ. J. Eleсtrochem., 2023, vol. 59, p. 635.]
- 22. Jordan, M., Electrodeposition of lead and lead alloys, in Modern electroplating, Schlesinger, M. and Paunovic, M., New Jersey, NJ: Wiley, 2010. p. 249.
- 23. Fil’, T.I., Khimchenko, Yu.I., Isai, V.N., and Romanova, A.V., Electrodeposition and an X-ray structural study of fine lead-bismuth alloy powders, Sov. Powder Metall. Met. Ceram., 1977, vol. 16, p. 167.
- 24. Поветкин, В.В., Шиблева, Т.Г. Электроосаждение и свойства сплавов висмута с легкоплавкими металлами. Защита металлов. 2006. Т. 42. № 5. С. 557. [Povetkin, V.V. and Shibleva, T.G., Electrodeposition and properties of bismuth alloys with low-melting metals, Protection of Metals, 2006, vol. 42, no. 5, p. 516.]
- 25. Сохраняева, А.С., Статкус, М.А., Цизин, Г.И., Золотов, Ю.А. Жидкостно-хроматографическое определение фенолов после проточного сорбционного концентрирования на сорбенте Strata-X. Журн. аналит. химии. 2010. Т. 65. № 11. С. 1181. [Sokhranyaeva, A.S., Statkus, M.A., Tsizin, G.I., and Zolotov, Y.A., Determination of phenols by liquid chromatography after online adsorption preconcentration on the Strata-X adsorbent, J. Anal. Chem., 2010, vol. 65, no. 11, p. 1155.]
- 26. Выдра, Ф., Штулик, К., Юлакова, Э. Инверсионная вольтамперометрия, М.: Мир, 1980. 278 с. [Vydra, F., Štulik, K., and Yulakova, E., Stripping voltammetry (in Russian), Moscow: Мir, 1980. 278 p.]
- 27. Yang, M. and Hu, Z., Electrodeposition of bismuth onto glassy carbon electrodes from nitrate solutions, J. Electroanal. Chem., 2005, vol. 583, p. 46.
- 28. Goldstein, J.I., Newbury, D.E., Michael, J.R., Ritchie, N.W.M., Scott, J.H.J., and Joy, D.C., Scanning electron microscopy and X-ray microanalysis, New York: Springer New York, 2018. 550 p.
