ENERGY EXCHANGE BETWEEN INTERACTION BEAMS IN PHOTOREFRACTIVE SBN CRYSTAL

Article Sidebar

Abstract views: 110
PDF Downloads: 51
pdf (rus) (Русский)
Published: Apr 15, 2019
Keywords:
фоторефрактивный кристалл, внешнее электрическое поле, двумерные световые пучки, супергауссов профиль, оптическая ось кристалла, оптимальные условия, энергетический обмен photorefractive crystal, external electric field, two-dimensional light beams, super-Gaussian profile, optical axis of the crystal, optimal conditions, energy exchange

Main Article Content

V. DAVYDOVSKAYA
Mozyr State Pedagogical University named after I.P.Shamyakin

Abstract

The features of the interaction of two-dimensional light beams in a SBN photorefractive crystal placed in an external constant electric field are established, depending on the location of the light beams relative to each other, as well as on the intensity vector of the external electric field. The conditions for energy exchange between in-phase two-dimensional light beams were found during their interaction in an SBN photorefractive crystal placed in an external electric field applied along the optical axis of the crystal.

Article Details

How to Cite
DAVYDOVSKAYA, V. (2019). ENERGY EXCHANGE BETWEEN INTERACTION BEAMS IN PHOTOREFRACTIVE SBN CRYSTAL. Vestnik of Polotsk State University. Part C. Fundamental Sciences, (4), 101-108. Retrieved from https://journals.psu.by/fundamental/article/view/413
Issue
No. 4 (2019)
Section
Physics
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Author Biography

V. DAVYDOVSKAYA, Mozyr State Pedagogical University named after I.P.Shamyakin

канд. физ.-мат. наук, доц.

References

Solymar, L. The physics and applications of photorefractive materials / L. Solymar, D.J. Webb, A. Grunnet-Jepsen. – Oxford : Clarendon Press, 1996. – 494 p.

Петров, М.П. Фоторефрактивные кристаллы в когерентной оптике / М.П. Петров, С.И. Степанов, А.В. Хоменко. – СПб. : Наука, 1992. – 320 с.

Cuniot-Ponsard, M. Strontium Barium Niobate Thin Films for Dielectric and Electro-Optic Applications. Ferroelectrics - Material Aspects / M. Cuniot-Ponsard. – InTech. –2011. – P. 498–518.

Francombe, M.H. The relation between structure and ferroelectricity in lead barium and strontium niobates / M.H. Francombe / Acta Cryst. – 1960. – Vol. 13. – Pt. 2. – P. 131–140.

Stoyanov, L. Initiating self-focusing of beams carrying spatial phase singularities /L. Stoyanov, G. Maleshkov, I. Stefanov, A. Dreischuh / JOSA B. – 2014. – Vol. 31. – P. 1159–1164.

Keshavarz, A. Propagation of Incoherently Coupled Soliton Pairs in Photorefractive Crystals and their Self-Deflection / A. Keshavarz, Z. Abbasib, M. Hatamia / International Journal of Optics and Photonics. – 2012. – Vol. 6, No. 1. – P. 13–20.

Measuring the relation between pulse front tilt angle and beam size for ultrashort pulses / N. Dimitrov [et al.] / Bulgarian Journal of Physics. – 2016. – Vol. 43. – P. 21–29.

Soliton formation by decelerating interacting Airy beams / F. Diebel [et al.] / Optics Express. – 2015. – Vol. 23, Is.19 – P. 24351–24361.

Observation of spatially oscillating solitons in photonic lattices / F Diebel [et al.] / New J. Phys. – 2016. – Vol. 18. – P. 053038:8.

Photorefractive writing and probing of anisotropic linear and non-linear lattices / R. Allio [et al.] / Journal of Optics– 2015. – Vol. 17, No.2 – P. 049601:10.

Stimulated Raman scattering of 18 picosecond laser pulses in strontium barium niobate crystal / T.T. Basiev [et al.] / Laser Phys. Lett. – 2012. – Vol. 9, No.7 – P. 519–523.

Investigations on Fe-doped strontium barium niobate, single phase ferroelectric and magnetodielectric compounds / S.H Kshirsagar [et al.] / Journal of advanced dielectrics. – 2015. – Vol. 5. – No. 1. – P. 1550001:8.

Effect of Ni doping on ferroelectric, dielectric and magneto dielectric properties of strontium barium niobate ceramics / S. H. Kshirsagar [et al.] / Indian Journal of Pure & Applied Physics. – 2015. – Vol. 53. – P. 119–124.

Electronic and Optical Properties of Strontium Barium Niobate Single Crystals / B. Andriyevsky [et al.] / Ferroelectrics. – 2012. – Vol. 426. – P. 194–205.

Двухфотонное межзонное поглощение в кристаллах ниобата бария-стронция / П.Г. Зверев [и др.] / Квантовая электроника. – 2012. – Т. 42, № 7. – С. 595–599.

Ferroelectric and dielectric characterization studies on relaxor-and ferroelectric-like strontium-barium niobates / K. Matyjasek [et al.] / Condensed Matte Physic. – 2013. – Vol. 16., No. 3 – P. 31701:1.

Calvo M.L. Optical Waveguides: From Theory to Applied Technologies 1st Edition / M.L. Calvo, V. Lakshminarayanan. – CRC Press, 2007. – 424 p.

Coherence Controlled Soliton Interactions / T-S. Ku [et al.] / Phys Rev Lett. – 2005. – Vol. 94, No.6 – P. 063904:4.

Interactions of incoherent localized beams in a photorefractive medium / Y. Zhang [et al.] / JOSA B. – 2014. – Vol. 31, Is.10 – P. 2258–2262.

Взаимодействие экранирующих солитонов в кубических оптически активных фоторефрактивных кристаллах / В. В. Шепелевич [и др.] // Квантовая электроника. – 2005. – Т.35, № 3. – С. 351–355.

Counterpropagating optical beams and solitons / M.S. Petrovihc [et al.] / Laser Photonics Rev. – 2011. – Vol. 5, No.10 – P. 214–233.

Shen, M. Control on the anomalous interactions of Airy beams in nematic liquid crystals / M. Shen, W. Li, R.-K. Lee / Optics Express. – 2016. – Vol. 24, Is.8 – P. 8501–8511.

Zozulya, A.A. Propagation of an optical beam in a photorefractive medium in the presence of a photogalvanic nonlinearity or an externally applied electric field // A.A. Zozulya, D.Z. Anderson // Phys. Rev. A. – 1995. – Vol. 51. – P. 1520–1532.

Interaction of spatial photorefractive solitons / W. Królikowski [et al.] // Quantum Semiclass. Opt. – 1998. – Vol. 10. – P. 823–837.

Stepken, A. Anisotropic interaction of three-dimensional spatial screening solitons / A. Stepken, F. Kaiser, M.R. Belić // J. Opt. Soc. Am. B. – 2000. – Vol. 17. – P. 68–77.

Holographic storage in electrooptic crystals / N.V. Kukhtarev [et al.] // Ferroelectrics. – 1979. – Vol. 22, № 3–4. – P. 961–964.

Analysis of transverse Anderson localization in refractive index structures with customized random potential / M. Boguslawski [et al.] / Optics Express. – 2013. – Vol. 21, Is.26 – P. 31713–31724.

Królikowski, W. Photorefractive Solitons / W. Królikowski, B. Luther-Davies, C. Denz // IEEE Journal of Quantum Electron. – 2003. – Vol. 39, № 1. – P. 3–12.

Królikowski, W. Photorefractive materials and solitons / W. Królikowski, B. Luther-Davies, Y. Kivshar // Opt. Electron. Rev. – 2001. – Vol. 9, № 3. – P. 287–292.

Mitchel, A.R. Computational Methods in Partial Differential Equations / A.R. Mitchel. – New York: Wiley, 1969. – 255 p.

Lizhong, S. Modified finite-difference beam-propagation method based on the Douglas scheme / S. Lizhong, G.L. Yip // Opt. Lett. – 1993. – Vol. 18, № 15. – P. 1229–1231.

Interferometric measurements of the photoinduced refractive index profiles in photorefractive Bi12TiO20 / G.S. Garcia Quirino [et al.] // Opt. Commun. – 1996. – Vol. 123. – P. 597–602.

Roychoudhuri, C. The Nature of Light: What is a Photon? (Optical Science and Engineering) / C. Roychoudhuri, A.F. Kracklauer, K. Creath. – Taylor & Francis Inc. : CRC Press, 2008.

Design and Evaluation of Light Spread Function for Area-Adaptive LCD System / Y.-K. Cheng [et al.] // J. Display Technol. – 2009. – Vol. 5, № 2 – P. 66–71.

Dickey, F.M. Laser beam shaping theory and techniques / F.M. Dickey, S.C. Holswade. – New York : Marcel Dekker Inc., 2000. – 428 p.

Interaction of two-dimensional rectangular light beams in a photorefractive SBN crystal / D. Khmelnitsky [et al.] / Ferroelectrics. – 2009. – Vol. 390. – P. 116–127.