Optical Properties of Dy3+ Doped Boro-tellurite Glasses
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Abstract
Abstract: Dy3+-doped glasses with various compositions (30+x)B2O3+ (60-x)TeO2 + 9Na2O + 1Dy2O3 (x = 10 and 20) were prepared by a melt–quenching technique. The specifically structural properties of boro-tellurite glasses with the high borate content (> 30 mol%) was reflected in the unusually large values of the Judd-Ofelt parameters Ω2 and Ω6 . The CIE chromaticity color coordinates were calculated from the luminescence spectra of Dy3+ ions of the glasses with the different compositions and all of them were located in the white light zone of the color coordination diagram.
Keywords: Boro-tellurite, Dy3+, white light.References
[1] R.-Y. Yang and H.-L. Lai, Microstructure, and luminescence properties of LiBaPO4:Dy3+ phosphors with various Dy3+ concentrations prepared by microwave assisted sintering, Journal of Luminescence 145 (2014) 49-54.
[2] Z. Yang, Y. Liu, C. Liu, F. Yang, Q. Yu, X. Li, and F. Lu, Multiwavelength excited white-emitting Dy3+ doped Sr3Bi(PO4)3 phosphor, Ceramics International 39 (2013) 7279-7283.
[3] J. Pisarska, R. Lisiecki, W. Ryba-Romanowski, T. Goryczka, and W.A. Pisarski, Unusual luminescence behavior of Dy3+-doped lead borate glass after heat treatment, Chemical Physics Letters 489 (2010) 198-201.
[4] O. Ravi, C.M. Reddy, B.S. Reddy, and B. Deva Prasad Raju, Judd–Ofelt analysis and spectral properties of Dy3+ ions doped niobium containing tellurium calcium zinc borate glasses, Optics Communications 312 (2014) 263-268
[5] S. Bigotta, M. Tonelli, E. Cavalli, and A. Belletti, Optical spectra of Dy3+ in KY3F10 and LiLuF4 crystalline fibers, Journal of Luminescence 130 (2010) 13-17.
[6] L. Jyothi, G. Upender, R. Kuladeep, and D.N. Rao, Structural, thermal, optical properties and simulation of white light of titanium-tungstate-tellurite glasses doped with dysprosium, Materials Research Bulletin 50 (2014) 424-431.
[7] A.M. Babu, B.C. Jamalaiah, J.S. Kumar, T. Sasikala, and L.R. Moorthy, Spectroscopic and photoluminescence properties of Dy3+-doped lead tungsten tellurite glasses for laser materials, Journal of Alloys and Compounds 509 (2011) 457-462.
[8] B. Shanmugavelu and V.V.R.K. Kumar, Luminescence studies of Dy3+ doped bismuth zinc borate glasses, Journal of Luminescence 146 (2014) 358-363.
[9] S. Tanabe, J. Kang, T. Hanada, and N. Soga, Yellow/blue luminescences of Dy3+-doped borate glasses and their anomalous temperature variations, Journal of Non-Crystalline Solids 239 (1998) 170-175
[10] M.V. Sasi kumar, D. Rajesh, A. Balakrishna, and Y.C. Ratnakaram, Optical absorption and photoluminescence properties of Dy3+ doped heavy metal borate glasses – Effect of modifier oxides, Journal of Molecular Structure 1041 (2013) 100-105
[11] M.V. Sasi kumar, D. Rajesh, A. Balakrishna, and Y.C. Ratnakaram, Optical absorption and photoluminescence properties of Dy3+ doped heavy metal borate glasses – Effect of modifier oxides, Journal of Molecular Structure 1041 (2013) 100-105
[12] G.W. Brady, Structure of Tellurium Oxide Glass, The Journal of Chemical Physics 27 (1957) 300-303.
[13] R.W. Adams, Infra-red absorption due to water in glasses. Physics and Chemistry of Glasses, 2 (1961) 39-49.
[14] S.Rada, M.Culea, E. Culea, Structure of TeO2.B2O3 glasses inferred from infrared spectroscopy and DFT calculations, Journal of Non-Crystalline Solids 354 (2008) 5491–5495
[15] Y.S. Bobovich, A.K.Yakhkind, Zhur. Struk. Khim. 4, (1963), 924
[16] V.M.Orera, P.J.Alonso, R.Cases, R.Alcala, Physics and Chemistry of Glasses 29 (1998) 59
[17] K. Damak, E.S. Yousef, C. Rüssel, and R. Maâlej, White light generation from Dy3+ doped tellurite glass, Journal of Quantitative Spectroscopy and Radiative Transfer 134 (2014) 55-63.
[18] P. Babu and C.K. Jayasankar, Spectroscopic properties of Dy3+ ions in lithium borate and lithium fluoroborate glasses, Optical Materials 15 (2000) 65-79
[19] W.A. Pisarski, J. Pisarska, L. Żur, and T. Goryczka, Structural and optical aspects for Eu3+ and Dy3+ ions in heavy metal glasses based on PbO–Ga2O3–XO2 (X = Te, Ge, Si), Optical Materials 35 (2013) 1051-1056.
[20] S.A. Saleem, B.C. Jamalaiah, M. Jayasimhadri, A. Srinivasa Rao, K. Jang, and L. Rama Moorthy, Luminescent studies of Dy3+ ion in alkali lead tellurofluoroborate glasses, Journal of Quantitative Spectroscopy and Radiative Transfer 112 (2011) 78-84.
[21] M. Jayasimhadri, K. Jang, H.S. Lee, B. Chen, S.-S. Yi, and J.-H. Jeong, White light generation from Dy3+-doped ZnO–B2O3–P2O5 glasses, Journal of Applied Physics 106 (2009) 013105.
[2] Z. Yang, Y. Liu, C. Liu, F. Yang, Q. Yu, X. Li, and F. Lu, Multiwavelength excited white-emitting Dy3+ doped Sr3Bi(PO4)3 phosphor, Ceramics International 39 (2013) 7279-7283.
[3] J. Pisarska, R. Lisiecki, W. Ryba-Romanowski, T. Goryczka, and W.A. Pisarski, Unusual luminescence behavior of Dy3+-doped lead borate glass after heat treatment, Chemical Physics Letters 489 (2010) 198-201.
[4] O. Ravi, C.M. Reddy, B.S. Reddy, and B. Deva Prasad Raju, Judd–Ofelt analysis and spectral properties of Dy3+ ions doped niobium containing tellurium calcium zinc borate glasses, Optics Communications 312 (2014) 263-268
[5] S. Bigotta, M. Tonelli, E. Cavalli, and A. Belletti, Optical spectra of Dy3+ in KY3F10 and LiLuF4 crystalline fibers, Journal of Luminescence 130 (2010) 13-17.
[6] L. Jyothi, G. Upender, R. Kuladeep, and D.N. Rao, Structural, thermal, optical properties and simulation of white light of titanium-tungstate-tellurite glasses doped with dysprosium, Materials Research Bulletin 50 (2014) 424-431.
[7] A.M. Babu, B.C. Jamalaiah, J.S. Kumar, T. Sasikala, and L.R. Moorthy, Spectroscopic and photoluminescence properties of Dy3+-doped lead tungsten tellurite glasses for laser materials, Journal of Alloys and Compounds 509 (2011) 457-462.
[8] B. Shanmugavelu and V.V.R.K. Kumar, Luminescence studies of Dy3+ doped bismuth zinc borate glasses, Journal of Luminescence 146 (2014) 358-363.
[9] S. Tanabe, J. Kang, T. Hanada, and N. Soga, Yellow/blue luminescences of Dy3+-doped borate glasses and their anomalous temperature variations, Journal of Non-Crystalline Solids 239 (1998) 170-175
[10] M.V. Sasi kumar, D. Rajesh, A. Balakrishna, and Y.C. Ratnakaram, Optical absorption and photoluminescence properties of Dy3+ doped heavy metal borate glasses – Effect of modifier oxides, Journal of Molecular Structure 1041 (2013) 100-105
[11] M.V. Sasi kumar, D. Rajesh, A. Balakrishna, and Y.C. Ratnakaram, Optical absorption and photoluminescence properties of Dy3+ doped heavy metal borate glasses – Effect of modifier oxides, Journal of Molecular Structure 1041 (2013) 100-105
[12] G.W. Brady, Structure of Tellurium Oxide Glass, The Journal of Chemical Physics 27 (1957) 300-303.
[13] R.W. Adams, Infra-red absorption due to water in glasses. Physics and Chemistry of Glasses, 2 (1961) 39-49.
[14] S.Rada, M.Culea, E. Culea, Structure of TeO2.B2O3 glasses inferred from infrared spectroscopy and DFT calculations, Journal of Non-Crystalline Solids 354 (2008) 5491–5495
[15] Y.S. Bobovich, A.K.Yakhkind, Zhur. Struk. Khim. 4, (1963), 924
[16] V.M.Orera, P.J.Alonso, R.Cases, R.Alcala, Physics and Chemistry of Glasses 29 (1998) 59
[17] K. Damak, E.S. Yousef, C. Rüssel, and R. Maâlej, White light generation from Dy3+ doped tellurite glass, Journal of Quantitative Spectroscopy and Radiative Transfer 134 (2014) 55-63.
[18] P. Babu and C.K. Jayasankar, Spectroscopic properties of Dy3+ ions in lithium borate and lithium fluoroborate glasses, Optical Materials 15 (2000) 65-79
[19] W.A. Pisarski, J. Pisarska, L. Żur, and T. Goryczka, Structural and optical aspects for Eu3+ and Dy3+ ions in heavy metal glasses based on PbO–Ga2O3–XO2 (X = Te, Ge, Si), Optical Materials 35 (2013) 1051-1056.
[20] S.A. Saleem, B.C. Jamalaiah, M. Jayasimhadri, A. Srinivasa Rao, K. Jang, and L. Rama Moorthy, Luminescent studies of Dy3+ ion in alkali lead tellurofluoroborate glasses, Journal of Quantitative Spectroscopy and Radiative Transfer 112 (2011) 78-84.
[21] M. Jayasimhadri, K. Jang, H.S. Lee, B. Chen, S.-S. Yi, and J.-H. Jeong, White light generation from Dy3+-doped ZnO–B2O3–P2O5 glasses, Journal of Applied Physics 106 (2009) 013105.