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Structure analysis of terbium aluminosilicate glass
Published online by Cambridge University Press: 15 March 2011
Extract
Glasses rich in rare-earth ions have attracted a lot of interest due to their applications in optical isolators and optical amplifiers. Integrating optical isolators with various optoelectronic devices allows sources to be integrated with lower costs, easier alignment and longer lifetimes. Glasses rich in rare-earth ions have large Verdet constants, so large Faraday rotations. Among the rare-earth ions used in paramagnetic glasses, Tb3+ ions have largest Faraday rotation per ion and the glasses are transparent down to 1.6um. These glasses can also avoid the temperature incompatibility and lattice match problems which are encountered when magneto-optical garnets mare used for integration. The Tb3+doping is also widely used in optical amplifiers. In this paper we have explored the metastable phases present in the sputtered Tb-Al-Si-O system in order to fabricate paramagnetic films with the highest possible Faraday rotations, lowest optical losses and that are easily integrated with semiconductors. A broad peak was observed in the microdiffraction pattern around 2θ= 30deg. This peak corresponded with the close-packed Tb-O plane spacing (111 for FCC Tb4O7 or 002 for HCP Tb2O3), but it was an “amorphous” peak with a 5 deg FWHM. Amorphous films were obtained even when the Tb concentrations were very high. Since high concentrations of Tb are known to devitrify glasses, the discovery of a high-Tb concentrated glass is exciting.
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- Copyright © Materials Research Society 2004
References
References:
[1]
Levy, M., "Epitaxial liftoff of thin oxide layers: Yttrium iron garnets onto GaAs”, Appl. Phys. Lett., 71
2617–9 (1997).Google Scholar
[2]
Stadler, B. J. H. and Gopinath, A., “Magneto-optical garnet films made by reactive sputtering”, IEEE Trans,.Magn., 36, 3957–61, 2000.Google Scholar
[3]
Oliver, S. A., Chen, M. L., Kozulin, I., Yoon, S. D., Zuo, X., and Vittoria, C., “Growth and characterization of thick oriented Barium Hexaferrite films on MgO(111) substrates”, Apppl. Phys. Lett., 76, 3612–14, 2000.Google Scholar
[4]
Stadler, B., Yip, P., Li, Y., Cherif, M., Vaccaro, K. and Lorenzo, J., IEEE Trans. Mag., 38(3), 1564–7, 2002.Google Scholar
[5]
Rivera, L. J. Cruz, Pandit, S., Pieski, S., Cobian, R., Cherif, M., and Stadler, B.J.H., Proceedings of SPIE, 4284, 29–42, 2001.Google Scholar
[6]
Sung, Sang-Yeob, Kim, Na-Hyoung, and Stadler, B. J. H., Mat. Res. Sco. Symp. Proc., 768, G4.6.1, 2003.Google Scholar
[7]
Tanaka, Katsuhisa, Fujita, Koji, Matsuoka, Nobuaki, hirao, Kazuyuki, and Soga, Naohiro, “Large Faraday effect and local structure of alkali silicate glasses containing divalent europium ions”, J. Mater. Res., 13, 1989–1995, 1998.Google Scholar
[9]
Ballato, John and Snitzer, Elias, “Fabrication of fibers with high rare-earth concentrations for Faraday isolator applications”, Applied Optics, 34, 6848–6853, 1995
Google Scholar
[10]
Tanaka, Katsuhisa, Hirao, Kazuyuki and Soga, Naohiro, “Large Verdet constant of 30Tb2O370B2O3 glass”, Jpn. J. Appl. Phys., 34, 4825–4826, 1995.Google Scholar
[11]
Samson, B. N., Schweizer, T., Hewak, D. W., and Laming, R. I., “Properties of dysprosium-doped gallium lanthanum sulfide fiber amplifiers operating at 1.3um", Optics Letters, Vol. 22, No.10, 703–705, 1997.Google Scholar
[12]
Lee, Dong Jun, Heo, Jong, Park, Se Ho, “Energy transfer and 1.48 emission properties in chalcohalide glasses doped with Tm3+ and Tb3+
", Journal of Non-Crystalline Solids, 331, 184–189, 2003
Google Scholar