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Kvantovaya Elektronika, 2011, Volume 41, Number 10, Pages 863–868 (Mi qe14653)  

This article is cited in 10 scientific papers (total in 10 papers)

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Structural, optical, and spectroscopic properties and efficient two-micron lasing of new Tm3+:Lu2O3 ceramics

O. L. Antipova, S. Yu. Golovkina, O. N. Gorshkovb, N. G. Zakharova, A. P. Zinov'eva, A. P. Kasatkinb, M. V. Kruglovab, M. O. Marychevb, A. A. Novikova, N. V. Sakharovb, E. V. Chuprunovb

a Institute of Applied Physics, Russian Academy of Sciences, Nizhny Novgorod
b National Research Lobachevsky State University of Nizhny Novgorod

Abstract: The structural, optical, and spectroscopic properties of new Tm3+ : Lu2O3 laser ceramics are studied. The average size of a ceramic grain (crystallite) is found to be 540 – 560 nm. The absorption spectrum measured in the near-IR region shows that this ceramics can be pumped by commercially available laser diodes at wavelengths of 796 and 811 nm. The high-transmission region of the ceramics in the mid-IR region extends to 7 μm. Investigations of the luminescence spectrum in the region of 1.75 – 2.2 mm upon laserdiode pumping show strong lines peaked at wavelengths of 1942, 1965, and 2066 nm. Ellipsometric measurements yield refractive indices n ≈ 1.92 at the pump wavelength 796 nm and n ≈ 1.94 at the laser wavelength 2066 nm. Continuous-wave lasing of a Tm3+ : Lu2O3 ceramic laser at a wavelength of 2066 nm is demonstrated under diode-laser pumping at wavelengths of 796 and 811 nm.

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English version:
Quantum Electronics, 2011, 41:10, 863–868

Bibliographic databases:

PACS: 42.70.Hj, 81.05.Mh, 42.55.Rz, 42.60.Lh
Received: 06.05.2011
Revised: 10.08.2011

Citation: O. L. Antipov, S. Yu. Golovkin, O. N. Gorshkov, N. G. Zakharov, A. P. Zinov'ev, A. P. Kasatkin, M. V. Kruglova, M. O. Marychev, A. A. Novikov, N. V. Sakharov, E. V. Chuprunov, “Structural, optical, and spectroscopic properties and efficient two-micron lasing of new Tm3+:Lu2O3 ceramics”, Kvantovaya Elektronika, 41:10 (2011), 863–868 [Quantum Electron., 41:10 (2011), 863–868]

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    Erratum

    This publication is cited in the following articles:
    1. E.V. Ivakin, I.G. Kisialiou, O.L. Antipov, Optical Materials, 2012  crossref  isi  scopus
    2. Lagatsky A.A., Antipov O.L., Sibbett W., Opt. Express, 20:17 (2012), 19349–19354  crossref  adsnasa  isi  elib  scopus
    3. A. A. Lagatsky, Z. Sun, T. S. Kulmala, R. S. Sundaram, S. Milana, F. Torrisi, O. L. Antipov, Y. Lee, J. H. Ahn, C. T. A. Brown, W. Sibbett, A. C. Ferrari, Appl. Phys. Lett, 102:1 (2013), 013113  crossref  adsnasa  isi  elib  scopus
    4. Vetrovec J., Copeland D.A., Litt A.S., Briscoe E., SPIE Defense + Security (Baltimore, Maryland, United States, Sunday 17 April 2016), SPIE Proceedings, 9834, eds. Dubinskii M., Post S., Spie-Int Soc Optical Engineering, 2016, UNSP 983407  crossref  isi  scopus
    5. Zhang L., Hao Zh., Zhang X., Pan G.-H., Luo Y., Wu H., Ba X., Zhang J., Inorg. Chem., 56:21 (2017), 13062–13069  crossref  isi  scopus
    6. Baylam I., Canbaz F., Sennaroglu A., IEEE J. Sel. Top. Quantum Electron., 24:5 (2018), 1601208  crossref  isi  scopus
    7. Baylam I., Ozharar S., Sennaroglu A., Appl. Optics, 57:8 (2018), 1772–1776  crossref  isi  scopus
    8. Vetrovec J., Filgas D.M., Smith C.A., Copeland D.A., Litt A.S., Briscoe E., Schirmer E., Solid State Lasers Xxvii: Technology and Devices, Proceedings of Spie, 10511, eds. Clarkson W., Shori R., Spie-Int Soc Optical Engineering, 2018, UNSP 1051103  crossref  isi  scopus
    9. Hao Zh., Zhang L., Wang Yu., Wu H., Pan G.-H., Wu H., Zhang X., Zhao D., Zhang J., Opt. Mater. Express, 8:11 (2018), 3615–3621  crossref  isi
    10. Xiao Zh., Yu Sh., Li Yu., Ruan Sh., Kong L.B., Huang Q., Huang Zh., Zhou K., Su H., Yao Zh., Que W., Liu Y., Zhang T., Wang J., Liu P., Shen D., Allix M., Zhang J., Tang D., Mater. Sci. Eng. R-Rep., 139 (2020), UNSP 100518  crossref  isi  scopus
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