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Ferroelectrics Volume 183, 1996 - Issue 1
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Original Articles

Optical-damage-resistant impurities (Mg, Zn, In, Sc) in lithium niobate

T. Volk Institute of Crystallography Russian Acad. Sci., Moscow, 117333, Russia
,
M. Wöhlecke Institute of Crystallography Russian Acad. Sci., Moscow, 117333, Russia
,
N. Rubinina Institute of Crystallography Russian Acad. Sci., Moscow, 117333, Russia
,
A. Reichert Fachbereich Physik, Universität Osnabrück, D-49069, Osnabrück, Germany
&
N. Razumovski Moscow State University, Russia
Pages 291-300 | Received 04 Jul 1995, Published online: 26 Oct 2011

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K. Lengyel, Zs. Szaller, Á. Péter, K. Polgár & L. Kovács. (2008) Microscopic and Raman Spectroscopic Investigation of the Domain Structures in LiNbO3:Y:Mg Crystals. Ferroelectrics 368:1, pages 3-11.
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Ming-Hua Li, Yu-Heng Xu, Chun-Hui Yang, Chao-Zhong Zhao & Zong-Shu Shao. (2001) Growth and spectral properties of LiNbO3 doped with Zn. Ferroelectrics 261:1, pages 287-292.
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Articles from other publishers (31)

Nina Hong, Jiarong R. Cui, Hyun Jung Kim, Ross G. Shaffer & Nguyen Q Vinh. (2023) New insights into refractive indices and birefringence of undoped and MgO-doped lithium niobate crystals at high temperatures. Optical Materials 145, pages 114365.
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J.G. Murillo-Ramírez, C. Alvarez-Herrera, J. Cerón-Solís, G. Herrera-Pérez & J. Castillo-Torres. (2023) Point defects substitution mechanism in indium-doped LiNbO3 single crystals revealed by UV–Visible and Micro-Raman analysis. Optical Materials 142, pages 114050.
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Nikolay A. Viugin, Vladimir A. Khokhlov, Irina D. Zakiryanova, Vasiliy N. Dokutovich & Boris D. Antonov. (2022) Molten Chlorides as the Precursors to Modify the Ionic Composition and Properties of LiNbO3 Single Crystal and Fine Powders. Materials 15:10, pages 3551.
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N. V. Sidorov, N. A. Teplyakova, M. V. Smirnov & M. N. Palatnikov. (2021) Structural Defects and Photoluminescence in Zinc-Doped Lithium Niobate Crystals. Inorganic Materials 57:10, pages 1028-1034.
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N. A. Teplyakova, M. V. Smirnov, N. V. Sidorov & M. N. Palatnikov. (2021) Defects and Some Physical Properties of Nominally Pure and Zinc-Doped Lithium Niobate Crystals. Physics of the Solid State 63:9, pages 1317-1325.
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Alexander Vjacheslavovich Syuy, Nikolay N. Prokopiv, Nikolay V. Sidorov, Mikhail N. Palatnikov, Il'ya S. Dolgopolov, Marina S. Petrova & Elena A. Antonycheva. (2019) Determination of Electro-Optical Coefficients of Lithium Niobate Crystals. Key Engineering Materials 806, pages 175-179.
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Charlotte Cochard, Mael Guennou, Thiemo Spielmann, Niels van Hoof, Alexei Halpin & Torsten Granzow. (2018) Effect of optical damage resistant dopants on the dielectric properties of LiNbO3: Insight from broadband impedance spectroscopy and Raman scattering. Journal of Applied Physics 123:15.
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J.G. Murillo, G. Herrera, A. Vega-Rios, S. Flores-Gallardo, A. Duarte-Moller & J. Castillo-Torres. (2016) Effect of Zn doping on the photoluminescence properties of LiNbO3 single crystals. Optical Materials 62, pages 639-645.
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M Aillerie, P Bourson, M Mostefa, F Abdi & M D Fontana. (2013) Photorefractive Damage in congruent LiNbO 3 . Part II. Magnesium doped Lithium Niobate Crystals . Journal of Physics: Conference Series 416, pages 012002.
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F.Z. Fadil, M. Aillerie, T. Lamcharfi & F. Abdi. (2011) Synthesis and characterization of holmium doped lithium niobate powders. Ceramics International 37:7, pages 2281-2285.
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F. Abdi, M. Aillerie, P. Bourson & M. D. Fontana. (2009) Defect structure in Mg-doped LiNbO3: Revisited study. Journal of Applied Physics 106:3.
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T. S. Chernaya, T. R. Volk, I. A. Verin & V. I. Simonov. (2008) Threshold concentrations in zinc-doped lithium niobate crystals and their structural conditionality. Crystallography Reports 53:4, pages 573-578.
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K. Lengyel, L. Kovács, Á. Péter, K. Polgár & G. Corradi. (2007) The effect of stoichiometry and Mg doping on the Raman spectra of LiNbO3:Mg crystals. Applied Physics B 87:2, pages 317-322.
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Pratima Sen, Namita Sisodia & K.S. Bartwal. (2006) Influence of MgO doping on spontaneous polarization and second-order susceptibility in LiNbO3 crystals. Optical Materials 29:2-3, pages 206-210.
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Dongfeng Xue & Xiangke He. (2006) Dopant occupancy and structural stability of doped lithium niobate crystals. Physical Review B 73:6.
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C.-T. Chia, C.-C. Lee, P.-J. Chang, M.-L. Hu & L. J. Hu. (2005) Substitution mechanism of ZnO-doped lithium niobate crystal determined by powder x-ray diffraction and coercive field. Applied Physics Letters 86:18.
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Bo Fu, Guoquan Zhang, Lubing Zhao, Haijun Qiao, Qingjun Xu, Yan Shen, Jingjun Xu, Yongfa Kong, Jun Sun & Shaolin Chen. (2005) Studies on the ultraviolet-light-induced absorption changes in congruent LiNbO3:Mg. Studies on the ultraviolet-light-induced absorption changes in congruent LiNbO3:Mg.
Qingjun Xu, Guoquan Zhang, Haijun Qiao, Bo Fu, Yan Shen, Jingjun Xu, Yongfa Kong, Jun Sun & Shaolin Chen. (2005) Studies on thermal activation energy of ultraviolet-induced small polarons O- in damage-resistant lithium niobate crystals. Studies on thermal activation energy of ultraviolet-induced small polarons O- in damage-resistant lithium niobate crystals.
Yasuo Tomita, Steven Sunarno & Guoquan Zhang. (2004) Ultraviolet-light-gating two-color photorefractive effect in Mg-doped near-stoichiometric LiNbO_3. Journal of the Optical Society of America B 21:4, pages 753.
Crossref
Philipp Dittrich, Germano Montemezzani, Masayuki Habu, Makoto Matsukura, Shunji Takekawa, Kenji Kitamura & Peter Günter. (2004) Sub-millisecond interband photorefraction in magnesium doped lithium tantalate. Optics Communications 234:1-6, pages 131-136.
Crossref
Haijun Qiao, Jingjun Xu, Qiang Wu, Xuanyi Yu, Qian Sun, Xinzheng Zhang, Guangyin Zhang & Tatyana R. Volk. (2003) An increase of photorefractive sensitivity in In:LiNbO3 crystal. Optical Materials 23:1-2, pages 269-272.
Crossref
M.-L Hu, C.-T Chia, J.Y Chang, W.-S Tse & J.-T Yu. (2003) Low-temperature Raman study of zinc-doped lithium niobate crystal powders. Materials Chemistry and Physics 78:2, pages 358-362.
Crossref
Steven Sunarno, Yasuo Tomita & Guoquan Zhang. (2002) Light-induced absorption changes in In-doped congruent LiNbO3. Applied Physics Letters 81:24, pages 4505-4507.
Crossref
D. Xue & K. Kitamura. (2002) Dielectric characterization of the defect concentration in lithium niobate single crystals. Solid State Communications 122:10, pages 537-541.
Crossref
D. Xue, K. Betzler & H. Hesse. (2001) Induced Li-site vacancies and non-linear optical behavior of doped lithium niobate crystals. Optical Materials 16:3, pages 381-387.
Crossref
D. Xue, K. Betzler & H. Hesse. (2001) Second order nonlinear optical properties of In-doped lithium niobate. Journal of Applied Physics 89:2, pages 849-854.
Crossref
T. S. Chernaya, B. A. Maksimov, T. R. Volk, N. M. Rubinina & V. I. Simonov. (2001) Zn atoms in lithium niobate and mechanism of their insertion into crystals. Journal of Experimental and Theoretical Physics Letters 73:2, pages 103-106.
Crossref
D. Xue, K. Betzler & H. Hesse. (2000) Chemical bond analysis of the second order nonlinear optical behavior of Zn-doped lithium niobate. Optics Communications 182:1-3, pages 167-173.
Crossref
D Xue, K Betzler & H Hesse. (2000) Chemical bond analysis of the second-order nonlinear optical behaviour of Mg-doped lithium niobate. Journal of Physics: Condensed Matter 12:28, pages 6245-6252.
Crossref
Kan Chen, Ming-sheng Zhang (M S Zhang)Wan-chun Chen. (1999) Photoinduced Light Scattering in Co- and Cr-Doped Lithium Niobate. Chinese Physics Letters 16:2, pages 137-139.
Crossref
Tatyana Volk, Boris Maximov, Sergei Sulyanov, Natalya Rubinina, Farid Abdi, Michel Aillerie, Marc Fontana, Patrice Bourson & Manfred Woehlecke. (1999) Optical and Photorefractive Properties of Optical-Damage Resistant LiNbO3Zn Crystals Related to Structure Parameters. Optical and Photorefractive Properties of Optical-Damage Resistant LiNbO3Zn Crystals Related to Structure Parameters.

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