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Effect of dispersion order on the spectral degree of polarization of stochastic electromagnetic pulsed beams

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The analytical expression for the cross-spectral density function of stochastic electromagnetic Bessel–Gauss pulsed beams through a dispersive aperture lens is derived and used to study the changes in the spectral degree of polarization in an optical focus system. The changes in the spectral degree of polarization at the focal plane and on the z-axis are performed in the case of dispersion-free, dispersion of the first, second, and higher orders, respectively. It is shown that the dispersion affects the peak value of the spectral degree of polarization, and the higher order dispersion leads to a more obvious effect on the peak value of the spectral degree of polarization at the focal plane. On the z-axis, the spectral degree of polarization in the dispersion-free case is different form that in the dispersion case, however, the dispersion of different orders almost has the same effect on the spectral degree of polarization. The results obtained in this paper may be crucial for high precision laser detection.
Czasopismo
Rocznik
Strony
147--158
Opis fizyczny
Bibliogr. 24 poz., wykr.
Twórcy
autor
  • College of Physics and Electronic Information, Luoyang Normal College, Luoyang 471022, China
autor
  • College of Physics and Electronic Information, Luoyang Normal College, Luoyang 471022, China
autor
  • College of Physics and Electronic Information, Luoyang Normal College, Luoyang 471022, China
autor
  • College of Physics and Electronic Information, Luoyang Normal College, Luoyang 471022, China
autor
  • College of Physics and Electronic Information, Luoyang Normal College, Luoyang 471022, China
Bibliografia
  • [1] WOLF E., Unified theory of coherence and polarization of random electromagnetic beams, Physics Letters A 312(5–6), 2003, pp. 263–267.
  • [2] WOLF E., Correlation-induced changes in the degree of polarization, the degree of coherence, and the spectrum of random electromagnetic beams on propagation, Optics Letters 28(13), 2003, pp. 1078–1080.
  • [3] WOLF E., Introduction to the Theory of Coherence and Polarization of Light, Cambridge University Press, Cambridge, 2007, pp. 108–178.
  • [4] KOROTKOVA O., WOLF E., Changes in the state of polarization of a random electromagnetic beam on propagation, Optics Communications 246(1–3), 2005, pp. 35–43.
  • [5] ROYCHOWDHURY H., PONOMARENKO S.A., WOLF E., Change in the polarization of partially coherent electromagnetic beams propagating through the turbulent atmosphere, Journal of Modern Optics 52(11), 2005, pp. 1611–1618.
  • [6] ROYCHOWDHURY H., AGRAWAL G.P., WOLF E., Changes in the spectrum, in the spectral degree of polarization, and in the spectral degree of coherence of a partially coherent beam propagating through a gradient-index fiber, Journal of the Optical Society of America A 23(4), 2006, pp. 940–948.
  • [7] PÄÄKKÖNEN P., TURUNEN J., VAHIMAA P., FRIBERG A.T., WYROWSKI F., Partially coherent Gaussian pulses, Optics Communications 204(1–6), 2002, pp. 53–58.
  • [8] LAJUNEN H., VAHIMAA P., TERVO J., Theory of spatially and spectrally partially coherent pulses, Journal of the Optical Society of America A 22(8), 2005, pp. 1536–1545.
  • [9] LAJUNEN H., TURUNEN J., VAHIMAA P., TERVO J., WYROWSKI F., Spectrally partially coherent pulse trains in dispersive media, Optics Communications 255(1–3), 2005, pp. 12–22.
  • [10] LAJUNEN H., TERVO J., TURUNEN J., VAHIMAA P., WYROWSKI F., Spectral coherence properties of temporally modulated stationary light sources, Optics Express 11(16), 2003, pp. 1894–1899.
  • [11] TORRES-COMPANY V., MÍNGUEZ-VEGA G., LANCIS J., FRIBERG A.T., Controllable generation of partially coherent light pulses with direct space-to-time pulse shaper, Optics Letters 32(12), 2007, pp. 1608–1610.
  • [12] CHAOLIANG DING, LIUZHAN PAN, BAIDA LÜ, Characterization of stochastic spatially and spectrally partially coherent electromagnetic pulsed beams, New Journal of Physics 11, 2009, article 083001.
  • [13] MIN YAO, YANGJIAN CAI, KOROTKOVA O., QIANG LIN, ZHAOYING WANG, Spatio-temporal coupling of random electromagnetic pulses interacting with reflecting gratings, Optics Express 18(21), 2010, pp. 22503–22514.
  • [14] CHAOLIANG DING, LIUZHAN PAN, BAIDA LÜ, Changes in the spectral degree of polarization of stochastic spatially and spectrally partially coherent electromagnetic pulses in dispersive media, Journal of the Optical Society of America B 26(9), 2009, pp. 1728–1735.
  • [15] ZHIGANG ZANG, MINATO T., NAVARETTI P., HINOKUMA Y., DUELK M., VELEZ C., HAMAMOTO K., High-power (> 110 mW) superluminescent diodes by using active multimode interferometer, IEEE Photonics Technology Letters 22(10), 2010, pp. 721–723.
  • [16] ZHIGANG ZANG, KEISUKE MUKAI, NAVARETTI P., DUELK M., VELEZ C., HAMAMOTO K., Thermal resistance reduction in high power superluminescent diodes by using active multi-mode interferometer, Applied Physics Letters 100, 2012, article 031108.
  • [17] ZANG Z.G., MUKAI K., NAVARETTI P., DUELK M., VELEZ C., HAMAMOTO K., High power and stable high coupling efficiency (66%) superluminescent light emitting diodes by using active multi-mode interferometer, IEICE Transactions on Electronics E94-C(5), 2011, pp. 862–864.
  • [18] VOIPIO T., SETÄLÄ T., FRIBERG A.T., Partial polarization theory of pulsed optical beams, Journal of the Optical Society of America A 30(1), 2013, pp. 71–81.
  • [19] KOROTKOVA O., VISSER T.D., WOLF E., Polarization properties of stochastic electromagnetic beams, Optics Communications 281(4), 2008, pp. 515–520.
  • [20] PATERSON C., SMITH R., Higher-order Bessel waves produced by axicon-type computer-generated holograms, Optics Communications 124(1–2), 1996, pp. 121–130.
  • [21] COLLINS S.A., Lens-system diffraction integral written in terms of matrix optics, Journal of the Optical Society of America 60(9), 1970, pp. 1168–1177.
  • [22] WEN J.J., BREAZEALE M.A., A diffraction beam field expressed as the superposition of Gaussian beams, The Journal of the Acoustical Society of America 83(5), 1988, pp. 1752–1756.
  • [23] AGRAWAL G.P., Far-field diffraction of pulsed optical beams in dispersive media, Optics Communications 167(1–6), 1999, pp. 15–22.
  • [24] GUILD J.B., XU C., WEBB W.W., Measurement of group delay dispersion of high numerical aperture objective lenses using two-photon excited fluorescence, Applied Optics 36(1), 1997, pp. 397–401.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-28242af2-9de7-4e60-b4aa-178e793db756
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