Electronic Structure of Tin Dioxide Thin Films

M. D. Manyakin; Манякин М. Д.; S. I. Kurganskii; Курганский С. И.

doi:10.31857/S1028096023080101

Electronic Structure of Tin Dioxide Thin Films

作者: Manyakin M.D.¹, Kurganskii S.I.¹
隶属关系:
1. Voronezh State University
期: 编号 8 (2023)
页面: 89-97
栏目: Articles
URL: https://journals.rcsi.science/1028-0960/article/view/137802
DOI: https://doi.org/10.31857/S1028096023080101
EDN: https://elibrary.ru/OAWJAQ
ID: 137802

如何引用文章

全文:

开放存取

##reader.subscriptionAccessGranted##
受限制的访问

订阅存取

详细
作者简介
参考
补充文件
统计

详细

The electronic structure of tin dioxide (001) nanofilms in a wide range of thicknesses has been modeled by the method of linearized coupled plane waves in the framework of the density functional theory in the generalized gradient approximation. The spectra of the total and local partial densities of electronic states characterizing the electronic structure of atoms spread out in various layers of the films under consideration are calculated. It is shown that the influence of the surface leads to the appearance of energy features of the density of states localized in the bang gap. A model describing the layered transformation of the electronic structure during the transition from the surface to the volume of the crystal SnO₂ is proposed. A film (001) with a thickness of 8 elementary cells for SnO₂ is considered as a model object. It is found that the surface electronic states arising in the band gap in SnO₂(001) films are spatially strongly localized – their density drops to almost zero by the third atomic layer from the surface. The applicability of the combined use of the layered superlattice method and the core hole method for modeling X-ray absorption spectra in nanofilms is considered. It is established that when calculating the XANES spectra for atoms in the surface layer of SnO₂ nanofilms, the influence exerted by the surface is significantly greater than the influence exerted by the core hole. Therefore, when calculating the XANES spectra for atoms in the surface layer of nanofilms, the core hole can be neglected in the first approximation.

关键词

tin dioxide, SnO₂, nanofilms, surface, computer modeling, electronic structure, density of electronic states, X-ray absorption spectroscopy, XANES.

作者简介

M. Manyakin

Voronezh State University

编辑信件的主要联系方式.
Email: manyakin@phys.vsu.ru
Russia, 394018, Voronezh

S. Kurganskii

Voronezh State University

Email: manyakin@phys.vsu.ru
Russia, 394018, Voronezh

参考

Orlandi M.O. Tin Oxide Materials Synthesis, Properties, and Applications. Elsevier Inc., 2020. 628 p.
Nascimento E.P., Firmino H.C.T., Neves G.A., Menezes R.R. // Ceram. Int. 2022. V. 48. Iss. 6. P. 7405. http://doi.org./10.1016/j.ceramint.2021.12.123
Dalapati G.K., Sharma H., Guchhait A., Chakrabarty N., Bamola P., Liu Q., Saianand G., Krishna A.M.S., Mukhopadhyay S., Dey A., Wong T.K.S., Zhuk S., Ghosh S., Chakrabortty S., Mahata C., Biring S., Kumar A., Ribeiro C.S., Ramakrishna S., Chakraborty A.K., Krishnamurthy S., Sonar P., Sharma M. // J. Mater. Chem. A. 2021. V. 9. Iss. 31. P. 16621. http://doi.org./10.1039/D1TA01291F
Nwanna E.C., Imoisili P.E., Jen T.-C. // J. King Saud University – Sci. 2022. V. 34. Iss. 5. P. 102123. http://doi.org./10.1016/j.jksus.2022.102123
Feng X., Ma J., Yang F., Ji F., Zong F., Luan C., Ma H. // Solid State Comm. 2007. V. 144. Iss. 7–8. P. 269. http://doi.org./10.1016/j.ssc.2007.07.028
Luan C., Ma J., Yu X., Zhu Z., Mi W., Lv Y. // Vacuum. 2012. V. 86. Iss. 9. P. 1333. http://doi.org./10.1016/j.vacuum.2011.12.009
Godin T.J., LaFemina J.P. // Phys. Rev. B. 1993. V. 47. Iss. 11. P. 6518. http://doi.org./10.1103/PhysRevB.47.6518
Maki-Jaskari M.A., Rantala T.T. // Phys. Rev. B. 2002. V. 65. Iss. 24. P. 245428. http://doi.org./10.1103/PhysRevB.65.245428
Duan Y. // Phys. Rev. B. 2008. V. 77. Iss. 4. P. 045332. http://doi.org./10.1103/PhysRevB.77.045332
Floriano E.A., de Andrade Scalvi L.V., Sambrano J.R., Geraldo V. // Mater. Res. 2010. V. 13. № 4. P. 437. http://doi.org./10.1590/S1516-14392010000400004
Mounkachi O., Salmani E., Lakhal M., Ez-Zahraouy H., Hamedoun M., Benaissa M., Kara A., Ennaoui A., Benyoussef A. // Solar Energy Mater. Solar Cells. 2016. V. 148. P. 34. http://doi.org./10.1016/j.solmat.2015.09.062
Wang M., Feng T., Ren J., Gao L., Li H., Hao Z., Yue Y., Zhou T., Hou D. // J. Phys. Chem. Solids. 2022. V. 163. P. 110586. http://doi.org./10.1016/j.jpcs.2022.110586
Dos Santos S.B.O., Boratto M.H., Ramos Jr. R.A., Scalvi L.V.A. // Mater. Chem. Phys. 2022. V. 278. P. 125571. http://doi.org./10.1016/j.matchemphys.2021.125571
Кристаллографическая и кристаллохимическая База данных для минералов и их структурных аналогов. (2022) Институт экспериментальной минералогии РАН. http://database.iem.ac.ru/mincryst/. Дата посещения 15.12.2022
Бекенев В.Л., Зубкова С.М. // ФТП. 2017. Т. 51. Вып. 1. С. 26. http://doi.org./10.21883/FTP.2017.01.43991.8226
Манякин М.Д., Курганский С.И., Дубровский О.И., Лихачев Е.Р. // Конденсированные среды и межфазные границы. 2017. Т. 19. № 4. С. 542. http://doi.org./10.17308/kcmf.2017.19/235
Chen J.G. // Surf. Sci. Rep. 1997. V. 30. Iss. 1–3. P. 1. http://doi.org./10.1016/S0167-5729(97)00011-3
Hebert C., Luitz J., Schattschneider P. // Micron. 2003. V. 34. Iss. 3–5. P. 219. http://doi.org./10.1016/s0968-4328(03)00030-1
Mizoguchi T., Tanaka I., Yoshioka S., Kunisu M., Yamamoto T., Ching W.Y. // Phys. Rev. B. 2004. V. 70. Iss. 4. P. 045103. http://doi.org./10.1103/PhysRevB.70.045103
Курганский С.И., Манякин М.Д., Дубровский О.И., Чувенкова О.А., Турищев С.Ю., Домашевская Э.П. // ФТТ. 2014. Т. 56. № 9. С. 1690. http://doi.org./10.1134/S1063783414090170
Manyakin M.D., Kurganskii S.I., Dubrovskii O.I., Chuvenkova O.A., Domashevskaya E.P., Ryabtsev S.V., Ovsyannikov R., Parinova E.V., Sivakov V., Turishchev S.Yu. // Mater. Sci. Semicond. Proc. 2019. V. 99. P. 28. http://doi.org./10.1016/j.mssp.2019.04.006
Blaha P., Schwarz K., Tran F., Laskowski R., Madsen G.K.H., Marks L.D. // J. Chem. Phys. 2020. V. 152. P. 074101. http://doi.org./10.1063/1.5143061
Perdew J.P., Yue W. // Phys. Rev. B. 1986. V. 33. Iss. 12. P. 8800. http://doi.org./10.1103/PhysRevB.33.8800
Tang P., Ren S., Zhang J., Wua L., Li W., Li B., Zeng G., Wang W., Liu C., Feng L. // Mater. Sci. Semicond. Proc. 2020. V. 113. P. 105020. http://doi.org./10.1016/j.mssp.2020.105020
Manyakin M.D., Kurganskii S.I. // J. Phys.: Conf. Ser. 2020. V. 1658. P. 012032. http://doi.org./10.1088/1742-6596/1658/1/012032
Wen Z., Tian-mo L., Xiao-fei L. // Physica B: Cond. Matter. 2010. V. 405. P. 3458. http://doi.org./10.1016/j.physb.2010.05.023
Kufner S., Schleife A., Hoffling B., Bechstedt F. // Phys. Rev. B. 2012. V. 86. P. 075320. http://doi.org./10.1103/PhysRevB.86.075320
Rachut K., Körber C., Brötz J., Klein A. // Phys. Status Solidi A. 2014. V. 211. Iss. 9. P. 1997. http://doi.org./10.1002/pssa.201330367
Akgul F.A., Gumus C., Er A.O., Farha A.H., Akgul G., Ufuktepe Y., Liu Z. // J. Alloys Compd. 2013. V. 579. P. 50. http://doi.org./10.1016/j.jallcom.2013.05.057
Sanjines R., Coluzza C., Rosenfeld D., Gozzo F., Almeras Ph., Levy F., Margaritondo G. // J. Appl. Phys. 1993. V. 73. Iss. 8. P. 3997. http://doi.org./10.1063/1.352865
Nagasawa Y., Choso T., Karasuda T., Shimomura S., Ouyang F., Tabata K., Yamaguchi Y. // Surf. Sci. 1999. V. 433–435. P. 226. http://doi.org./10.1016/S0039-6028(99)00044-8