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科学研究

玻璃结构技术和设备公司科研和技术人员多年来一直在开发和制造各种玻璃结构的实验样品,已被俄罗斯和国外领先科学团体用于科学研究和高科技产品的开发。研制出的产品:

光子晶体纤维

Волокно под электронным микроскопомФотонный кристалл

 

这些纤维通过包层的不断周期性反射传导光,其对多个传播方向和辐射波长具有禁带作用。 在这种情况下,光可以在中空纤维中传播,因此在这种纤维中非线性小,材料(光学玻璃)吸收损耗也小。 这种纤维的实例是:

  • 用于传导大功率光的空心光纤[1]

  • 具有较大正交极化波传播常量差异的空心光纤 [2]

微结构纤维

Микроструктура Микроструктуры под электронным микроскопомМикроструктуры под электронным микроскопомМикроструктуры под электронным микроскопом

 

在这些纤维中,光沿着实心的或具有一定结构的纤芯传播,,包层具有周期性或接近周期性结构,其平均有效折射率小于纤芯。因为磁场在纤芯中局部化,纤维的非线性程度非常高,并且它们可以用于非线性效应,如由短纤维和强大的光脉冲激发下产生超连续谱、光学谐波、总频和差频的观察。使用多组分光学玻璃制造的非线性比石英玻璃高出约2个数量级的纤维,可以观察到在短长度纤维中的非线性影响,从而可以降低光学玻璃中可能达到3dB / m那样的损耗的影响。这种纤维的实例是:

  • 具有较大正交极化波传播常量差异的实心光纤

  • 用于生成超宽频超连续能谱的光纤,频宽超过2个八度音阶。 其生成使用在包层中形成基本单元格的两个边缘相交叉形成的纤芯。

  • 用于观察与纳米孔包层形成频率转换的光纤。

纤维开发过程包括计算光纤横截面中的场分布和计算所选光纤横向模式的群速度色散以及非线性系数。

计算使用平面波方法,该方法考虑到制造光纤的材料可能存在各向异性,还使用波束传播法,使用我们自己的软件模块。

载有有关玻璃结构技术和设备公司制造的纤维的应用信息的主要出版物列表。

由于出现更新的出版物,链接可能会被调整。

光子晶体和显微组织纤维

  1. A.B. Fedotov, P. Zhou, A.N. Naumov, V.V. Temnov, V.I. Beloglazov, N.B. Skibina, L.A. Mel’nikov, A.V. Shcherbakov, A.P. Tarasevitch, D. Von der Linde, A.M. Zheltikov / Spectral broadening of 40-fs Ti:sapphire laser pulses in photonic-molecule modes of a cobweb-microstructure fiber // Appl. Phys. B 75, 621–627 (2002).
     Загрузить документ в формате Adobe Acrobat® (236 KB)

  2. S.O. Konorov, A.B. Fedotov, O.A. Kolevatova, V.I. Beloglazov, N.B. Skibina, A.V. Shcherbakov, E. Wintner. and A.M. Zheltikov / Laser breakdown with millijoule trains of picosecond pulses transmitted through a hollow-core photonic-crystal fibre // J. Phys. D: Appl. Phys. 36 (2003) 1–7
     Загрузить документ в формате Adobe Acrobat® (428 KB)

  3. S.O. Konorov, O.A. Kolevatova, A.B. Fedotov, E.E. Serebryannikov, D.A. Sidorov-Biryukov, J.M. Mikhailova, A.N. Naumov, V.I. Beloglazov, N.B. Skibina, L.A. Mel’nikov, A.V. Shcherbakov and A. M. Zheltikov / Waveguide Modes of Electromagnetic Radiation in Hollow-Core Microstructure and Photonic-Crystal Fibers // Journal of Experimental and Theoretical Physics, Vol. 96, No. 5, 2003, pp. 857–869.
     Загрузить документ в формате Adobe Acrobat® (454 KB)

  4. S.O. Konorov, A.B. Fedotov, O.A. Kolevatova, V.I. Beloglazov, N.B. Skibina, A.V. Shcherbakov and A. M. Zheltikov / Waveguide Modes of Hollow Photonic-Crystal Fibers // JETP Letters, Vol. 76, No. 6, 2002, pp. 341–345.
     Загрузить документ в формате Adobe Acrobat® (311 KB)

  5. S.O. Konorov, A.B. Fedotov, D.A. Sidorov-Biryukov, V.I. Beloglazov, N.B. Skibina, A.V. Shcherbakov and A.M. Zheltikov / Hollow-core photonic-crystal fibers optimized for four-wave mixing and coherent anti-Stokes Raman scattering // J. Raman Spectrosc. 2003; 34: 000–000
     Загрузить документ в формате Adobe Acrobat® (199 KB)

  6. A.N. Naumov, A.B. Fedotov, I. Bugar, D. Chorvat, Jr., V.I. Beloglazov, S.O. Konorov, L.A. Mel’nikov, N.B. Skibina, D.A. Sidorov-Biryukov, E.A. Vlasova, V.B. Morozov, A.V. Shcherbakov, D. Chorvat and A.M. Zheltikov / Supercontinuum Generation in Photonic-Molecule Modes of Microstructure Cobweb Fibers and Photonic-Crystal Fibers with Femtosecond Pulses of Tunable 1.1–1.5-μm Radiation // Laser Physics, Vol. 12, No. 8, 2002, pp. 1191–1198.
     Загрузить документ в формате Adobe Acrobat® (462 KB)

  7. A.B. Fedotov, A.N. Naumov, S.O. Konorov, V.I. Beloglazov, L.A. Mel’nikov, N.B. Skibina, D.A. Sidorov-Biryukov, A.V. Shcherbakov and A.M. Zheltikov / Photonic-Molecule Modes of a Microstructure Cobweb Fiber // Laser Physics, Vol. 12, No. 11, 2002, pp. 1363–1367.
     Загрузить документ в формате Adobe Acrobat® (70 KB)

  8. A.N. Naumov, A.B. Fedotov, A.M. Zheltikov, V.V. Yakovlev, L.A. Mel’nikov, V.I. Beloglazov, N.B. Skibina and A.V. Shcherbakov / Enhanced χ(3) interactions of unamplified femtosecond Cr:forsterite laser pulses in photonic-crystal fibers // Vol. 19, No. 9/September 2002/J. Opt. Soc. Am. B 2183.
     Загрузить документ в формате Adobe Acrobat® (316 KB)

  9. A.B. Fedotov, S.O. Konorov, O.A. Kolevatova, V.I. Beloglazov, N.B. Skibina, L.A. Mel’nikov, A.V. Shcherbakov, A.M. Zheltikov / Waveguiding properties and the spectrum of modes of hollow-core photonic-crystal fibres // Quantum Electronics 33(3) 271-274 (2003).
     Загрузить документ в формате Adobe Acrobat® (1 835 KB)

  10. S.O. Konorov, A.B. Fedotov, A.A. Ivanov, M.V. Alfimov, V.I. Beloglazov, N.B. Skibina, A.A. Podshivalov, A.N. Petrov, A.V. Shcherbakov, A.M. Zheltikov / Guiding Femtosecond Second-Harmonic Pulses of a Cr:Forsterite Laser through Hollow-Core Photonic-Crystal Fibers // Laser Physics, Vol. 13, No. 8, 2003, pp. 1046–1049.
     Download document in Adobe Acrobat® format (94 KB)

  11. A.B.Fedotov, A.A.Ivanov, M.V. Alfimov, V.I.Beloglasov, L.A.Melnikov, Yu.S.Skibina, A.M.Zheltikov / Tuning the Photonic Band Gap of Sub-500-nm-Pitch Holey Fibers in the 930-1030-nm Range // Laser Physics. 2000. V.10. N.5. P.1086.

  12. L.A.Melnikov, Yu.P.Sinichkin, E.A.Romanova, I.V.Elterman, O.N.Kozina, Yu.S.Skibina, T.M.Benson, P.Sewell, I.S.Nefedov, V.I.Beloglasov, N.B.Skbinz / Quasi-1D and -2D photonic crysta and multi-layered fibers: manufacturing and theory // International conference proceedings. Praga. May 2000.

  13. A.M.Zheltikov, A.B.Fedotov, A.A.Ivanov, M.V.Alfimov, D.Chorvat, D.Chorvat Jr., L.A.Melnikov, V.I.Beloglasov, Yu.S.Skibina, A.P.Tarasevich, and D. von der Linde / Holey Fibers 0.4-32 mm-Lattice-Consultant Photonic Band-Gap Cladding: Fabrication, Characterization, and nonlinear optical Measurments.

  14. M.V.Alfimov, M.Zheltikov, A.A.Ivanov, V.I.Beloglasov, B.A.Kirilov, S.A.Magnitckii, A.V.Tarasishin, A.B.Fedotov, L.A.Melnikov N.B..Skibina / Photonic crystal fibers with a Photonic Band Gap Tunable within the Range of 930-1030 nm // JETP LETT. 200. V.71. PP. 489.

  15. E.V.Becker, E.A.Romanova, L.A.Melnikov, Yu.P.Sinichkin, V.Yu.Sorokin, I.V.Elterman, N.B.Skibina, V.I.Beloglazov, A.V.Sherbakov, V.V.Baturin, T.M.Benson, P.Sewell / Glass photonic crystals: fabrication, optical properties and applications // IEEE LEOS Annual Meeting 2001, 12-15 Nov. San-Diego, US. Conference Proceedings. 2 pages.

微结构玻璃纤维技术

  1. V.I.Beloglasov, S.P.Souchoveev, N.V.Suetin / Three-dimentional micron and submicron structures based on fiberglass technology // Indo-Russian Workshop on Micromechanical systems. 2-4 Fev., 1999, New-Dehli, India. SPIE Proceedings. 1999. V.3903. PP. 134-140.

  2. В.И.Белоглазов, С.П.Суховеев, Н.В.Суетин / создание микронных и субмикронных трех-мерных структур с использованием стекловолоконных технологий // Микросистемная техника. 2000. № 1. стр. 6-9.

X-射线光学

  1. V.A.Arkadiev, V.I.Beloglasov, A.A.Bzhaumiknoff, H.Gorny, N.Langhoff, Z.Margushev, J. Schmalz, R.Wedell / Poly-capillary structure as X-Ray window for differential vacuum pumping // Institute fuer Geraetebau GmbH (Germany) [3444-37].

  2. V.I.Beloglasov, A.Erco et al / Glass capillary for use with synchrotron radiation // ICOM’2001.

  3. A.Bjeoumikov et al / New generation of polycapillary lenses — manufacturing and applications // ICOM’2001.

微机械

  1. S.P.Soukhoveev, V.P.Stepanov, V.I.Beloglasov, N.B.Skibina, A.V.Stcherbakov, N.V.Suetin / Fiber Glass Structure as basic elements of moving actuators for microrobots operated by umbilical cable // International Workshop on Micro robots: Micro Machines and Systems. 1999. 24-25 Nov. Moscow. Russia. IARP Proceedings. PP. 185-190.

  2. S.P.Soukhoveev / Non-Flat Surface Micromatching Without Lithography for MEMS by use of Fiber Glass Substrates. International conference on modern problems of development and application of sensors and Micro Systems’s Technology. Conference Proceedings. P. 268.

  3. S.P.Soukhoveev, V.I.Beloglasov, A.V.Scherbakov, N.V.Suetin / ACI-MEMS from fiber glasses ACE.

微光学

  1. E.V.Becker, E.A.Romanova, L.A.Melnikov, T.M.Benson, P.Sewell / All-optical power limiting in waveguides with periodically distributed Kerr-like nonlinearity // Applied Physics B. 2001 (to be published).

其他

  1. A.A.Bzhaumiknoff, J. Schmalz, R.Wedell, V.I.Beloglasov, N.F.Lebedev / Polycapillary conic collimator for micro-XRF // Institute fuer Geraetebau GmbH (Russia) [3444-36].