ArticleName |
Producing high-purity zinc oxide
for photonics technologies |
ArticleAuthorData |
D. Mendeleev University of Chemical Technology of Russia, Moscow, Russia:
V. A. Solomatina, 4th year Student, e-mail: viktoria20000000@mail.ru M. B. Grishechkin, Lead Engineer, Candidate of Chemical Sciences, e-mail: grimb@mail.ru M. P. Zykova, Researcher, Candidate of Chemical Sciences, e-mail: zykova_mp@inbox.ru I. Kh. Avetisov, Head of the Department of Chemistry and Technology of Crystals, Professor, Doctor of Chemical Sciences, e-mail: igor_avetisov@mail.ru |
Abstract |
The authors developed a procedure for synthetizing high-purity zinc oxide by precipitation from a solution with the subsequent high-temperature treatment in oxygen. Metallic zinc additionally purified by vacuum distillation, nitric acid and aqua ammonia with total impurities not exceeding 10–4 % wt. were used as incoming substances for the synthesis. It is found that to produce a single-phase product as zinc oxide powder containing no nitrate and amine complexes, the precipitation should be conducted at a zinc concentration in solution of 2 mol/l and pH = 7.5. Impurities of iron, chromium, aluminum, barium, molybdenum and sodium are removed at the stage of forming the intermediate precipitate at pH = 5. The yield of the final high-purity product is 59%. A scanning electron microscopy method was used to study precipitate morphology before high-temperature annealing and after it. It is shown that the final product is powder formed from well-faceted crystallites represented by hexagonal prisms, 0.5–0.7 μm in diameter and 1.7–2.1 μm in length. The analysis of luminescence spectra indicated that synthetized and purified ZnO after high-temperature annealing showed low luminescence with a maximum value of 678 nm, while commercial ZnO powder was characterized by intensive luminescence with a maximum value of 522 nm, attributed to defects of non-stoichiometry and/or yttrium impurities. Chemical purity of zinc oxide synthetized and purified according to the developed procedure, as shown by inductively coupled plasma mass spectrometry, was 99.9993 % wt. by 67 impurity elements. The authors acknowledge K. I. Runina, an employee of the Department of Chemistry and Technology of Crystals, for her help with spectral studies. The research was conducted as part of funding applied research project of Mendeleev University of Chemical Technology of Russia No. ВИГ 2022-081. |
References |
1. Nadolinny V. A., Pavlyuk A. A., Solodovnikov S. F., Solodovnikovs Z. A., Zolotova E. S. et al. Structure and Properties of Crystals Li2Zn2(MoO4)3, activated by copper and chromium ions. Journal of Structural Chemistry. 2011. Vol. 52, No. 4. pp. 730–734. 2. Kadathala Linganna, Jung-Hwan In, Seon Hoon Kim, Karam Han, Ju Hyeon Choi. Engineering of TeO2 – ZnO – BaO-based glasses for mid-infrared transmitting optics. Materials. 2020. Vol. 13, No. 5829. pp. 1–14. 3. Rodimov O. I., Kiselev M. M., Setrakova E. S., Vartanyan M. A. Nonbismuth varistor ceramics based on zinc oxide. Modern technologies of composite materials : Proceedings of the 3rd All-Russian Scientific and Practical Youth Conference with an International Participation. Ufa : Bashkir State University, 2018. pp. 80–85. 4. Li L. E., Demyanets L. N., Nikitin S. V., Lavrikov A. S. Induced emission of disordered media based on ZnO crystal powders. Quantum Electronics. 2006. Vol. 36, No. 3. pp. 233, 234. 5. Grigoryev L. V., Morozov I. S., Zhuravlev N. V., Semenov A. A., Nikitin A. A. Photoluminescence and photoelectric properties of the ZnO – LiNbO3 thin-film structure in the ultraviolet and visible spectral regions. Semiconductors. 2020. Vol. 54, No. 3. pp. 232–237. 6. Ebrahimizadeh Abrishami M., Hosseini S. M., Attaran Kakhki E., Kompany A., Ghasemifard M. Synthesis and structure of pure and Mn-doped zinc oxide nanopowders. International Journal of Nanoscience. 2010. Vol. 9, No. 1-2. pp. 19–28. 7. Agarwal Happy, Venkat Kumar S., Rajeshkumar S. A review on green synthesis of zinc oxide nanoparticles – An eco-friendly approach. Resource-Efficient Technologies. 2017. Vol. 3. pp. 406–413. 8. Ashwath N., Bhat S. A., Almas F., Lokesh S. V., Sandeep G. S., Yelamaggad C. V. Green and low-cost synthesis of zinc oxide nanoparticles and their application in transistor-based carbon monoxide sensing. RSC Advances. 2020. Vol. 10. pp. 13532–13542. 9. Sabry R., Fikry M., Ahmed Ola S., F. Zedan A. Laser-induced synthesis of pure zinc oxide nanoflakes. IOP Conf. Series: Journal of Physics: Conf. Series. 2020. Vol. 1472. 012005. 10. Gunja Singh, Satya Pal Singh. Synthesis of zinc oxide by sol-gel method and to study its structural properties. AIP Conference Proceedings. 2020. Vol. 2220. 020184. 11. V. G. Lobanov, K. D. Naumov, S. A. Yakornov, M. A. Karpov, E. N. Selivanov et al. Method for producing zinc powder. Patent RF, No. 2757151. Applied: 27.02.2020. Published: 11.10.2021. Bulletin No. 29. 12. L. G. Baratov, L. A. Voropanova. Procedure for production of zinc oxide out of sulphate solution. Patent RF, No. 2393249. Applied: 20.10.2008. Published: 27.06.2010. Bulletin No. 18. 13. Nikolaeva S. N., Ivanov V. V., Shubin A. A. The chemical precipitation and thermal decomposition as the way for producing ultrafine zinc oxide forms. Journal of Siberian Federal University: Chemistry. 2010. Vol. 3, No. 2. pp. 153–173. 14. GOST 3640–94. Zinc. Specifications. Introduced: 01.01.1997.
15. GOST 11125–84. Super pure nitric acid. Specifications. Introduced: 01.01.1986. 16. GOST 24147–80. Super pure ammonia aqueous solution. Specifications. Introduced: 01.01.1981. 17. Pruszkowski E., Life P. E. Total quant analysis of teas and wines by ICP – MS. Field application report, ICP mass spectrometry. Shelton : Perkin Elmer Life and Analytical Sciences, 2004. 18. GOST 10262–73. Reagents. Zinc oxide. Specifications. Introduced: 01.01.1974. 19. Rodnyi P. A., Chernenko K. A., Venevtsev I. D. Mechanisms of ZnO luminescence in the visible spectral region. Optics and Spectroscopy. 2018. Vol. 125, No. 3. pp. 357–363. 20. Alivov Ya. I., Chukichev M. V., Nikitenko V. A. Green luminescence of zinc oxide films doped with copper by thermal diffusion. Semiconductors. 2004. Vol. 38, No. 1. pp. 34–38. 21. Ozgur U., Alivov Ya. I., Liu C. et al. A comprehensive review of ZnO materials and devices. Journal of Appl. Phys. 2005. Vol. 98, No. 4. 041301. |