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@article{PFMT_2021_4_a1,
author = {D. L. Kovalenko and M. Dobromir and V. V. Vaskevich and A. V. Semchenko and V. V. Sidski and O. I. Tyulenkova and Ya. A. Kosenok and G. Y. Ayvazyan and D. Luca},
title = {Development of a combined formation method of {ZnO/TiO}$_2$ nanotube},
journal = {Problemy fiziki, matematiki i tehniki},
pages = {11--16},
publisher = {mathdoc},
number = {4},
year = {2021},
language = {ru},
url = {http://geodesic.mathdoc.fr/item/PFMT_2021_4_a1/}
}
TY - JOUR AU - D. L. Kovalenko AU - M. Dobromir AU - V. V. Vaskevich AU - A. V. Semchenko AU - V. V. Sidski AU - O. I. Tyulenkova AU - Ya. A. Kosenok AU - G. Y. Ayvazyan AU - D. Luca TI - Development of a combined formation method of ZnO/TiO$_2$ nanotube JO - Problemy fiziki, matematiki i tehniki PY - 2021 SP - 11 EP - 16 IS - 4 PB - mathdoc UR - http://geodesic.mathdoc.fr/item/PFMT_2021_4_a1/ LA - ru ID - PFMT_2021_4_a1 ER -
%0 Journal Article %A D. L. Kovalenko %A M. Dobromir %A V. V. Vaskevich %A A. V. Semchenko %A V. V. Sidski %A O. I. Tyulenkova %A Ya. A. Kosenok %A G. Y. Ayvazyan %A D. Luca %T Development of a combined formation method of ZnO/TiO$_2$ nanotube %J Problemy fiziki, matematiki i tehniki %D 2021 %P 11-16 %N 4 %I mathdoc %U http://geodesic.mathdoc.fr/item/PFMT_2021_4_a1/ %G ru %F PFMT_2021_4_a1
D. L. Kovalenko; M. Dobromir; V. V. Vaskevich; A. V. Semchenko; V. V. Sidski; O. I. Tyulenkova; Ya. A. Kosenok; G. Y. Ayvazyan; D. Luca. Development of a combined formation method of ZnO/TiO$_2$ nanotube. Problemy fiziki, matematiki i tehniki, no. 4 (2021), pp. 11-16. http://geodesic.mathdoc.fr/item/PFMT_2021_4_a1/
[1] D. Eder, A.H. Windle, “Morphology control of CNT-TiO$_2$ hybrid materials and rutile nanotubes”, Material Chemistry, 18 (2008), 2036–2043 | DOI
[2] I. Kartini, Evana, Sutarno, Chotima, “Sol-gel derived ZnO nanorod templated TiO$_2$ nanotube synthesis for natural dye sensitized solar cell”, Advanced Materials Research, 896 (2014), 485–488 | DOI
[3] B.B. Cirak et al., “The enhanced light harvesting performance of dye-sensitized solar cells based on ZnO nanorod-TiO$_2$ nanotube hybrid photoanodes”, Optik, 203 (2020), 163963 | DOI
[4] C.F. Klingshirn, B.K. Meyer, A. Waag, A. Hoffmann, J. Geurts, Zinc oxide from fundamental properties towards novel applications, Springer-Verlag, Berlin–Heidelberg, 2010, 359 pp.
[5] U. Ozgur et al., “Acomprehensive review of ZnO materials and devices”, Journal of Applied Physics, 98 (2005), 1–103 | DOI
[6] I. Mohammadia, F. Zeraatpisheha, E. Ashiria, K. Abdib, “Solvothermal synthesis of g-C$_3$N$_4$ and ZnO nanoparticles on TiO$_2$ nanotube as photoanode in DSSC”, International Journal of Hydrogen Energy, 45:38 (2020), 18831–18839 | DOI
[7] Rui Li, Wein-Duo Yang, Liang-Sheng Qiang, Hsin-Yi Li, “Conveniently fabricated heterojunction ZnO/TiO$_2$ electrodes using TiO$_2$ nanotube arrays for dye-sensitized solar cells”, Journal of Power Sources, 220 (2012), 153–159 | DOI
[8] V.V. Vaskevich i dr., “Nanostrukturirovannye fotokataliticheskie zol-gel pokrytiya na osnove titana”, Problemy fiziki, matematiki i tekhniki, 2015, no. 4 (25), 7–10
[9] A. Roguskaa, M. Pisareka, M. Andrzejczuk, M. Lewandowska, “Synthesis and characterization of ZnO and Ag nanoparticle-loaded TiO$_2$ nanotube composite layers intended for antibacterial coatings”, Thin Solid Films, 553 (2014), 173–178 | DOI
[10] L.A. Pires et al., “Effects of ZnO/TiO$_2$ nanoparticle and TiO$_2$ nanotube additions to dense polycrystalline hydroxyapatite bioceramic from bovine bones”, Dental Materials, 36:2 (2020), e38–e46 | DOI
[11] S. Saint-Andrea, D. Rodriguez, P. Perillo, M. Barrera, “TiO$_2$ nanotubes antireflection coating design for GaAs solar cells”, Solar Energy Materials and Solar Cells, 230 (2021), 111201 | DOI