Energy efficiency of near infrared cobalt luminscence in ZnSe:Co determined by a photoacoustic method

Chrobak, Ł.; Maliński, M.; Strzałkowski, K.; Zakrzewski, Z.

Artykuł - szczegóły

Tytuł artykułu

Energy efficiency of near infrared cobalt luminscence in ZnSe:Co determined by a photoacoustic method

Autorzy

Chrobak Ł. , Maliński M. , Strzałkowski K. , Zakrzewski Z.

Wybrane pełne teksty z tego czasopisma

http://journals.pan.pl/dlibra/journal/opelre

Identyfikatory

Warianty tytułu

Języki publikacji

Abstrakty

The paper presents results of computations of the energy efficiency of the cobalt luminescence in ZnSe:Co determined by the photoacoustic method. The transmission spectra, photoacoustic experimental and theoretical spectra, and the frequency dependence on the photoacoustic amplitude characteristics are presented. From them, the energy efficiency of Co²⁺ the near infrared luminescence (3200 nm) was computed in the frame of new proposed photoacoustic model of computations of the luminescence energy efficiency.

Słowa kluczowe

semiconductors photoacoustic effect photoacoustic spectroscopy non-destructive testing

Wydawca

Stowarzyszenie Elektryków Polskich
Polska Akademia Nauk
Wojskowa Akademia Techniczna im. Jarosława Dąbrowskiego

Czasopismo

Opto-Electronics Review

Rocznik

2012

Tom

Vol. 20, No. 1

Strony

91--95

Opis fizyczny

Bibliogr. 19 poz., wykr.

Twórcy

autor

Chrobak Ł.

Department of Electronics and Computer Science, Technical University of Koszalin, 2 Śniadeckich Str, 75-453 Koszalin, Poland

autor

Maliński M.

miroslaw.malinski@tu.koszalin.pl

Department of Electronics and Computer Science, Technical University of Koszalin, 2 Śniadeckich Str, 75-453 Koszalin, Poland

autor

Strzałkowski K.

autor

Zakrzewski Z.

Bibliografia

1. A.P. Radliński, “On the properties of cobalt impurities in zinc selenide crystals II. The optical properties in near−infrared. 4A2(4F) 4T2(4F) transitions”, Phys. Status Solidi. B86, 41–46 (1978).
2. A.P. Radliński, “Infrared luminescence of cobalt impurities in II–VI compounds”, J. Lumin. 18/19, 147–150 (1979).
3. A.P. Radliński, “Position of the Co2+ level in wide gap II−VI semiconductors”, J. Phys. C: Solid State. 12, 4477–4482 (1979).
4. Z. Burshtein, Y. Shimony, R. Feldman, V. Krupkin, A. Glushko, and E. Galun, “Excited−state absorption at 1.57 μm in U2+:CaF2 and Co2+:ZnSe saturable absorbers”, Opt. Mater. 15, 285–291 (2001).
5. A.V. Podlipensky, V.G. Shcherbitsky, N.V. Kuleshov, V.P. Mikhailov, V.I. Levchenko, and V.N. Yakimovich, “Cr2+: ZnSe and Co2+:ZnSe saturable−absorber Q switches for 1.54−μm Er:glass lasers”, Opt. Lett. 24, 960–962 (1999).
6. L.D. Deloach, R.H. Page, G.D. Wilke, S.A. Payne, and W.F. Krupke, “Transition metal−doped zinc chalcogenides: spectroscopy and laser demonstration of a new class of gain media”, IEEE J. Quantum Elect. 32, 885–895 (1996).
7. A. Rosencwaig and A. Gersho, “Theory of acoustic effect with solids”, J. Appl. Phys. 47, 64–68 (1976).
8. C.A. Benett and R.R. Patty, “Thermal wave interferometry: a potential application of the photoacoustic effect”, Appl. Opt. 21, 49–52 (1982).
9. M. Maliński, “Temperature distribution formulae – applications in photoacoustics”, Arch. Acoust. 27, 217–220 (2002).
10. E. Rodriguez, J.O. Tocho, and F. Cusso, “Simultaneous multiple−wavelength photoacoustic and luminescence experiments: A method for fluorescent−quantum−efficiency determination”, Phys. Rev. B47, 14049–14053 (2000).
11. G.A. Torchia, D. Schinca, N.M. Khaidukov, and J.O. Tocho, “The luminescent quantum efficiency of Cr3+ ions in Cs2NaAlF6 single crystals”, Opt. Mater. 20, 301–304 (2002).
12. G.A. Torchia, J.A. Munoz, F. Cusso, F. Jague, and J.O. Tocho, “The luminescent quantum efficiency of Cr3+ ions in co−doped crystals of LiNbO3: ZnO determined by simultaneous multiple−wavelength photoacoustic and luminescence experiments”, J. Lumin. 92, 317–322 (2001)
13. M. Maliński, Ł. Chrobak, J. Zakrzewski, and K. Strzałkowski, ”Determination of the quantum efficiency of luminescence in Mn2+ ions in Zn0.75Be0.20Mn0.05Se crystals by the nondestructive photoacoustic metod”, Opt. Mater. 33, 75–78 (2010).
14. M. Maliński, “Influence of internal reflections of light on spectral characteristics of photoacoustic signal”, Opto−Electron. Rev. 18, 126–129 (2010).
15. F. Firszt, S. Łęgowski, H. Męczyńska, J. Szatkowski, W. Paszkowicz, and K. Godwod, “Growth and characterisation of Zn1–xBexSe mixed crystals”, J. Cryst. Growth 184, 1335–1338 (1998).
16. Ł. Chrobak and M. Maliński, “Transmission and absorption based photoacoustic methods of determination of the optical absorption spectra of Si samples – comparison”, Solid State Commun. 149, 1600–1602 (2009).
17. M. Maliński, and Ł. Chrobak, “Photoacousic operation modes for determination of the optical absorption spectra of SiGe mixed crystals”, Opto−Electron. Rev. 18, 19–25 (2010).
18. M. Maliński, and Ł. Chrobak, “Numerical analysis of absorption and transmission photoacoustic spectra of silicon samples with differently treated surfaces”, Opto−Electron. Rev. 19, 56–60 (2011).
19. M. Maliński, Ł. Chrobak, J. Zakrzewski, and K. Strzałkowski, “Photoacoustic method of determination of quantum efficiency of luminescence in Mn2+ ions in Zn1–x–yBexMnySe crystals”, Opto−Electron. Rev. 19, 183–188 (2011).

Typ dokumentu

Bibliografia

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