Üçdeğerlikli Erbiyum (Er+3) Katkılı BaTa2O6FosforununÜretimi, Yapısal Özellikleri ve Görünür–Yakın Kızılötesi Fotolüminesansı

Year 2017, Volume: 17 Issue: 2, 675 - 682, 31.08.2017

Mustafa İlhan

Abstract

Er+3 (üç değerlikli erbiyum iyonu) katkılı baryum tantalat fosforları katı hal reaksiyon metoduyla 1425 °C ’de 20 saat sinterlenerek üretilmiştir. Üretilen numuneler X–ışınları difraktometresi (XRD), taramalı elektron mikroskobu (SEM), enerji dağılımı spektroskopisi (EDS) ve görünür–lazer fotoluminesans (FL) analizleri ile karakterize edilmiştir. XRD analizinde, Er+3 katkılı BaTa2O6 yapısı %10 mol oranına kadar tek fazlı yapı özelliğini sürdürürken, %10 mol üzeri seviyelerde az oranda ErTaO4 fazı ortaya çıkmıştır. SEM analizlerinde Er+3 katkılı BaTa2O6 tanelerin boyutu katkı artışına bağlı olarak küçülme göstermiştir. Görünür FL analizlerinde, BaTa2O6:Er+3 fosforunun emisyon spektrumları ise 500 ile 690 nm dalgaboyları arasında olup, Er+3 iyonuna ait karakteristik emisyon pikleri gözlenmiştir. Ayrıca, Er+3 katkı artışına bağlı olarak emisyon azalması veya konsantrasyon sönümlemesi meydana gelmemiştir. BaTa2O6:Er+3 fosforlarının Uluslararası Aydınlatma Komisyonu (CIE) renklilik kordinatları diyagramında sarımsı-yeşil bölgede bulunmuştur. Yakın kızılötesi FL analizinde BaTa2O6:Er+3 fosforunun emisyon spektrumları 1450 ile 1650 nm arasında gözlemlenmiştir.

Keywords

“XRD”, “SEM–EDS”, “Nadir toprak iyonu”, “Fotolüminesans”, “Lazer”

References

• Marciniak, L., Stefanski, M., Tomala, R., Hreniak, D. and Strek, W., 2015. Synthesis and spectroscopic properties of RbLa1−xEuxP4O12 nanocrystals, J Alloy Compd, 624, 210–215.
• 2. Yang, H.M., Shi, J.X. and Gong, M.L., 2005. A novel red emitting phosphor Ca2SnO4:Eu3+, J Solid State Chem, 178, 917–920.
• 3. Yang , Z., Wu, H., Li, J., Shao, B., Qiu, J. and Song, Z., 2015. Slow light enhanced near infrared luminescence in CeO2: Er3+, Yb3+ inverse opal photonic crystals, J Alloy Compd, 641, 127–131.
• 4. Tamrakar, R.K., Bisen, D.P., Brahme, N., Sahu, I.P. and Upadhyay, K., 2015. Structural and luminescence behavior of Gd2O3:Er3+ phosphor synthesized by solid state reaction method, Optik, 126, 2654–2658.
• 5. Qiu, Z., Zhou, Y., Lu, M., Zhang, A. and Ma, Q., 2008. Combustion synthesis of three-dimensional reticularstructured luminescence SrAl2O4:Eu,Dy nanocrystals, Solid State Sci, 10, 629–633.
• 6. Rasool, S.N., Moorthy, L.R. and Jayasankar, C.K., 2013. Optical and luminescence properties of Dy3+ ions in phosphate based glasses, Solid State Sci, 22, 82–90.
• 7. Nakamura, S. and Fasol, G., 1997. The Blue Laser Diode: GaN Based Light Emitters and Laser, Springer, Berlin, Germany,.
• 8. Levine, A.K., and Palilla, F.C., 1964. A new, highly efficient red-emitting cathode luminescent phosphor (YVO4:Eu) for color television, Appl Phys Lett, 5, 5118–120.
• 9. Solé, J.G., Bausá, L.E., and Jaque, D., 2005. An Introduction to the Optical Spectroscopy of Inorganic Solids, John Wiley & Sons Ltd, England.
• 10. Layden, G.K., 1968. Dielectric and structure studies of hexagonal BaTa2O6, Mater Res Bull, 3, 349.
• 11. Kovba, L.M., Lykova, L.N., Paromova, M.V. and Lopato, L.M., 1977. Barium oxide–tantalum oxide system, Russ J Inorg Chem, 22, 1544.
• 12. Ichinose, N. and Shimada, T., 2006. Effect of grain size and secondary phase on microwave dielectric properties of Ba(Mg1/3Ta2/3)O3 and Ba([Mg, Zn]1/3Ta2/3)O3 systems, J Eur Ceram Soc, 26, 1755– 1759.
• 13. Lee, Y.H., Kim, Y.S., Kim, D.H. and Oh, M.H., 2000. Conduction mechanisms in barium tantalates films and modification of interfacial barrier height, IEEE T Electron Dev, 47, 71–76.
• 14. Kato, H. and Kudo, A., 1998. New tantalate photocatalysts for water decomposition into H2 and O2, Chem Phys Lett, 295, 487–492.
• 15. İlhan, M., 2014. Synthesis, structure and photoluminescence properties of Ho3+ doped TTB– BaTa2O6 phosphors, Solid State Sci, 38, 160–168.
• 16. Layden, G.K., 1967. Polymorphism of BaTa2O6, Mater Res Bull, 2, 533–539.
• 17. Magneli, A., 1949. The crystal structure of tetragonal potassium tungsten bronze, A Ark Kemi, 1, 213–221.
• 18. Hyde, B.G. and Keefe, M.O., 1973. Relations between the DO9(ReO3) structure type and some `bronze' and `tunnel' structures, Acta Crystallogr A, 29, 243–248.
• 19. Roulland, F., Josse, M. and Castel, E., 2009. Influence of ceramic process and Eu content on the composite multiferroic properties of The Ba6–2x Ln2xFe1+xNb9–xO30 TTB system, Solid State Sci, 11, 1709–1716.
• 20. Tressaud, A., 2011. Structural architecture and physical properties of some inorganic fluoride series: a review, J Fluorine Chem, 132, 651–659.
• 21. İlhan, M., Ekmekçi, M.K., Mergen, A. and Yaman, C., 2016. Synthesis and optical characterization of red– emitting BaTa2O6:Eu3+ phosphors, J Fluoresc, 26, 1671–1678.
• 22. Siqueira, K.P.F., Carmo, A.P., Bell, M.J.V. and Dias, A., 2016. Optical properties of undoped NdTaO4, ErTaO4 and YbTaO4 ceramics, J Lumin, 179, 146–153
• 23. Simon, A. and Ravez, J., 2006. Solid–state chemistry and non–linear properties of tetragonal tungsten bronzes materials, C R Chim, 9, 1268–1276.
• 24. İlhan, M., Mergen, A. and Yaman, C., 2013. Removal of iron from BaTa2O6 ceramic powder produced by high energy milling, Ceram Int, 39, 5741–5750.
• 25. Zhu, G., Ci, Z., Ma, C., Shi, Y. and Wang, Y., 2013. A novel red emitting phosphor of Eu3+ doped TTB–type niobate NaSr2Nb5O15 for white LEDs materials, Mater Res Bull, 48, 1995–1998.
• 26. Sadiq, I., Khan, I., Aen, F., Islam, M.U. and Rana, M.U., 2012. Rana, M.U., (2012). Influence of rare earth Ce3+ on structural, electrical and magnetic properties of Sr2+ based W–type hexagonal ferrite, Physica B, 407, 1256–1261.
• 27. Mumme, W.G., Grey, I.E., Roth, R.S. and Vanderah, T.A., 2007. Contrasting Oxide Crystal Chemistry of Nb and Ta: The Structures of the Hexagonal Bronzes BaTa2O6 and Ba0.93Nb2.03O6, J Solid State Chem, 180, 2429–2436.
• 28. Dieke, G.H., 1968. Spectra and Energy Levels of Rare Earth Ions in Crystals, Interscience Publishers, New York.
• 29. Gonçalves, H.R., Messaddeq, Y., Chiasera, A., Jes, Y., Ferrari, M., and Ribeiro, S.J.L., 2008. Erbium– activated silica–zirconia planar waveguides prepared by sol–gel route, Thin Solid Films, 516, 3094–3097.
• 30. Mortier, M., 2002. Between glass and crystal: Glass– ceramics, a new way for optical materials, J Solid State Chem, 62, 207–211.