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http://dx.doi.org/10.3807/COPP.2017.1.4.271

Spectral and Coherence Properties of Spectrally Partially Coherent Gaussian Schell-model Pulsed Beams Propagating in Turbulent Atmosphere  

Liu, Dajun (Department of Physics, Dalian Maritime University)
Luo, Xixian (Department of Physics, Dalian Maritime University)
Wang, Guiqiu (Department of Physics, Dalian Maritime University)
Wang, Yaochuan (Department of Physics, Dalian Maritime University)
Publication Information
Current Optics and Photonics / v.1, no.4, 2017 , pp. 271-277 More about this Journal
Abstract
Based on the extended Huygens-Fresnel principle, the analytical propagation formulae for spectrally partially coherent Gaussian Schell-model pulsed (SPGSMP) beams propagating in turbulent atmosphere have been derived. The influences of the parameters for turbulent atmosphere and SPGSMP beams on the on-axis and off-axis spectral shift and degree of coherence for SPGSMP beams propagating in turbulent atmosphere have been analyzed, using numerical calculations. The obtained results have potential applications for SPGSMP beams in free-space optical communication and laser lidar.
Keywords
Spectral shift; Degree of coherence; Partially coherent pulsed beam; Turbulent atmosphere;
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1 F. Wang, X. Liu, and Y. Cai, "Propagation of partially coherent beam in turbulent atmosphere: a review," Prog. Electromagn. Res. 150, 123-143 (2015).   DOI
2 Y. Baykal, "Intensity fluctuations of multimode laser beam in underwater medium," J. Opt. Soc. Am. A 32, 593598 (2015).
3 D. Liu, Y. Wang, and H. Yin, "Evolution properties of partially coherent flat-topped vortex hollow beam in oceanic turbulence," Appl. Opt. 54, 10510-10516 (2015).   DOI
4 D. Liu, Y. Wang, and H. Yin, "Propagation properties of partially coherent four-petal Gaussian vortex beams in turbulent atmosphere," Opt. Laser Tech. 78, 95-100 (2016).   DOI
5 H. Lajunen, P. Vahimaa, and J. Tervo, "Theory of spatially and spectrally partially coherent pulses," J. Opt. Soc. Am. A 22, 1536-1545 (2005).   DOI
6 C. Ding, L. Pan, and B. Lu, "Characterization of stochastic spatially and spectrally partially coherent electromagnetic pulsed beams," New J. Phys. 11, 083001 (2009).   DOI
7 X. Ji, E. Zhang, and B. Lu, "Spectral properties of chirped Gaussian pulsed beams propagating through the turbulent atmosphere," J. Mod. Opt. 54, 541-553 (2007).   DOI
8 X. Zeng, Z. Duan, L. Chang, and M. Zhang, "Spectral characteristics of chirped pulsed Gaussian beams propagating in turbulent atmosphere," High Power Laser and Particle Beam 25(9), 2257-2261 (2013).   DOI
9 Y. Yang and K. Duan, "Spectral anomalies of chirped Gaussian pulses from an annular aperture in the turbulent atmosphere," Opt. Eng. 48, 058001 (2009).   DOI
10 C. Ding, L. Pan, and B. Lu, "Effect of turbulence on the spectral switches of diffracted spatially and spectrally partially coherent pulsed beams in atmospheric turbulence," J. Opt. A: Pure Appl. Opt. 11, 105404(9pp) (2009).   DOI
11 M. Gao, Y. Li, H. Lv, and L. Gong, "Polarization properties of polarized and partially coherent Electromagnetic Gaussian-Schell model pulse beams on slant path in turbulent atmosphere," Infrared Phys. Technol. 67, 98-106 (2014).   DOI
12 O. Korotkova and E. Shchepakina, "Tuning the spectral composition of random beams propagating in free space and in a turbulent atmosphere," J. Opt. 15, 075714(6pp) (2013).   DOI
13 C. Chen, H. Yang, Y. Lou, and S. Tong, "Second-order statistics of Gaussian Schell-model pulsed beams propagating through atmospheric turbulence," Opt. Express 19, 15196-15204 (2011)   DOI
14 Y. Li, Z. Zhen, and M. Wang, "Partially coherent Gaussian-Schell model pulse beam propagating in slant atmospheric turbulence," Chin. Phys. B 23, 064216 (2014)   DOI
15 D. Liu, Y. Wang, G. Wang, H. Yin, and J. Wang, "The influence of oceanic turbulence on the spectral properties of chirped Gaussian pulsed beam," Opt. Laser Tech. 82, 76-81 (2016).   DOI
16 Z. Wang, L. Lu, P. Zhang, C. Fan, and X. Ji, "Broadening of ultra-short pulses propagating through weak-to-strong oceanic turbulence," Opt. Commun. 367, 95-101 (2016).   DOI
17 V. A. Banakh and I. N. Smalikho, "Fluctuations of energy density of short-pulse optical radiation in the turbulent atmosphere," Opt. Express 22, 22285-22297 (2014).   DOI
18 V. A. Banakh, L. O. Gerasimova, and I. N. Smalikho, "Numerical investigation of short-pulse laser radiation propagation in a turbulent atmosphere," Quantum Electron. 45, 258-264 (2015).   DOI
19 D. Liu, C. Ding, and B. Lu, "Spectral properties of spatially and spectrally partially coherent cosh-Gaussian pulsed beams focused by an aperture lens," Opt. Commun. 283, 379-385, (2010).   DOI
20 D. Liu, J. Cheng, S. Qi, W. Qang, and W. Qian, "Spatial correlation properties of focused spatially and spectrally partially coherent Hemite-Gaussian pulsed beams," Acta Phys. Sin. 61, 244202, (2012).
21 H. Yura, "Mutual coherence function of a finite cross section optical beam propagating in a turbulent medium," Appl. Opt. 11, 1399-1406 (1972).   DOI
22 R. Fante, "Two-position, two-frequency mutual-coherence function in turbulence," J. Opt. Soc. Am. 71, 1446-1451 (1981).   DOI
23 H. Yura and S. Hanson, "Optical beam wave propagation through complex optical systems," J. Opt. Soc. Am. A 4, 1931-1948 (1987).
24 D. Liu, C. Ding, and B. Lu, "Changes in the spectral degree of coherence and spectral intensity of spatially and spectrally partially coherent cosh-Gaussian pulsed beams in free space," Appl. Phys. B 98, 549, (2010).   DOI