Impact of joint turbulence of jet engine and marine environment on the propagation quality of partially coherent generalized Laguerre–Gaussian correlated Schell model beams

Nabil, H.; Balhamri, A.; BAYRAKTAR, Mert; CHATZINOTAS, Symeon; Belafhal, A.

doi:10.1007/s11082-024-06667-2

Article (Scientific journals)

Impact of joint turbulence of jet engine and marine environment on the propagation quality of partially coherent generalized Laguerre–Gaussian correlated Schell model beams

Nabil, H.; Balhamri, A.; BAYRAKTAR, Mert et al.

2024 • In Optical and Quantum Electronics, 56 (5)

Peer Reviewed verified by ORBi

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https://hdl.handle.net/10993/60676

DOI
10.1007/s11082-024-06667-2

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Keywords :

Electrical and Electronic Engineering; Atomic and Molecular Physics, and Optics; Electronic, Optical and Magnetic Materials

Disciplines :

Electrical & electronics engineering

Author, co-author :

Nabil, H.

Balhamri, A.

BAYRAKTAR, Mert ; University of Luxembourg > Interdisciplinary Centre for Security, Reliability and Trust (SNT) > SigCom

CHATZINOTAS, Symeon ; University of Luxembourg > Interdisciplinary Centre for Security, Reliability and Trust (SNT) > SigCom

Belafhal, A.

External co-authors :

yes

Language :

English

Title :

Impact of joint turbulence of jet engine and marine environment on the propagation quality of partially coherent generalized Laguerre–Gaussian correlated Schell model beams

Publication date :

29 March 2024

Journal title :

Optical and Quantum Electronics

ISSN :

0306-8919

eISSN :

1572-817X

Publisher :

Springer Science and Business Media LLC

Volume :

Issue :

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://link.springer.com/content/pdf/10.1007/s11082-024-06667-2.pdf

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since 01 April 2024

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M. Abramowitz Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables 1970 Washington U.S Department of Commerce
L.C. Andrews R.L. Phillips Laser Beam Propagation through Random Media 2005 Bellingham SPIE
Y. Baykal Higher-order laser beam scintillation in weakly turbulent marine atmospheric medium J. Opt. Soc. Am. A Opt. Image Sci. vis. 2016 33 758 763 2016JOSAA.33.758B
M. Bayraktar Performance of Airyprime beam in turbulent atmosphere Photon Netw. Commun. 2021 41 274 279
M. Bayraktar Propagation of partially coherent hyperbolic sinusoidal Gaussian beam in biological tissue Optik 2021 245 2021Optik.245p7741B
M. Bayraktar Near field propagation of hollow higher-order cosh-Gaussian beam in jet engine induced turbulence Phys. Scr. 2022 97 2022PhyS..97h5503B
M. Bayraktar B. Akın M.B. Işık Propagation of hyperbolic sinusoidal Gaussian beam in jet engine induced turbulence Opt. Quant. Electron. 2022 54
A. Belafhal S. Hennani L. Ez-zariy A. Chafiq K. Mohammed Propagation of truncated Bessel-modulated Gaussian beams in turbulent atmosphere Phy. Chem. News. 2011 62 36 43
A. Belafhal S. Chib F. Khannous T. Usman Evaluation of integral transforms using special functions with applications to biological tissues Comput. Appl. Math. 2021 40 4266697
J. Cang P. Xiu X. Liu Propagation of Laguerre–Gaussian and Bessel-Gaussian Schell-model beams through paraxial optical systems in turbulent atmosphere Opt. Laser Technol. 2013 54 35 41 2013OptLT.54..35C
Y. Chen Y. Cai Generation of a controllable optical cage by focusing a Laguerre–Gaussian correlated Schell-model beam Opt. Lett. 2014 39 2549 2552 2014OptL..39.2549C
R. Chen L. Liu S. Zhu G. Wu F. Wang Y. Cai Statistical properties of a Laguerre–Gaussian Schell-model beam in turbulent atmosphere Opt. Express 2014 22 1871 1883 2014OExpr.22.1871C
Y. Chen J. Gu F. Wang Y. Cai Self-splitting properties of a Hermite-Gaussian correlated Schell-model beam Phys. Rev. A 2015 91 2015PhRvA.91a3823C
M. Cheng L. Guo Y. Zhang Scintillation and aperture averaging for Gaussian beams through non-Kolmogorov maritime atmospheric turbulence channels Opt. Express 2015 23 32606 32621 2015OExpr.2332606C
S. Chib L. Dalil-Essakali A. Belafhal Evolution of the partially coherent generalized flattened Hermite-Cosh-Gaussian beam through a turbulent atmosphere Opt. Quant. Electron. 2020 52 484 500
S. Chib L. Dalil-Essakali A. Belafhal Comparative analysis of some Schell-model beams propagating through turbulent atmosphere Opt. Quant. Electron. 2022 54 175 191
S. Chib M. Bayraktar A. Belafhal Theoretical and computational study of a partially coherent laser beam in a marine environment Phys. Scr. 2022 98 015513 015526 2023PhyS..98a5513C
S. Chib F. Khannous A. Belafhal Propagation of General Model vortex higher-order cosh-Gaussian beam in maritime turbulence Opt. Quant. Electron. 2023 971 1 15
X. Cui X. Yin H. Chang Z. Sun Y. Wang Q. Tian G. Wu Xin., X. Analysis of the orbital angular momentum spectrum for Laguerre-Gaussian beams under moderate-to-strong marine-atmospheric turbulent channels Opt. Commun. 2018 426 471 476 2018OptCo.426.471C
Y. Dan B. Zhang Beam propagation factor of partially coherent flat-topped beams in a turbulent atmosphere Opt. Express 2008 16 15563 15575 2008OExpr.1615563D
C. Ding O. Korotkova D. Li D. Zhao L. Pan Propagation of Gaussian Schell-model beams through a jet engine exhaust Opt. Express 2020 28 1037 1050 2020OExpr.28.1037D
A.A.A. Ebrahim M.A. Swillam A. Belafhal Atmospheric turbulent effects on the propagation properties of a general model vortex higher-order Cosh-Gaussian beam Opt. Quant. Electron. 2023 55 1 16
K. Elmabruk H.T. Eyyuboğlu Analysis of flat-topped Gaussian vortex beam scintillation properties in atmospheric turbulence Opt. Eng. 2019 58 066115 066115 2019OptEn.58f6115E
A. Erdelyi W. Magnus F. Oberhettinger F.G. Tricomi Tables of Integral Transforms 1954 New York McGraw–Hill Book Company
H.T. Eyyuboğlu Propagation and coherence properties of higher order partially coherent dark hollow beams in turbulence Opt. Laser Technol. 2008 40 156 166 2008OptLT.40.156E
H.T. Eyyuboğlu Y. Baykal A. Falits Scintillation behavior of Laguerre Gaussian beams in strong turbulence Appl. Phys. B 2011 104 1001 1006 2011ApPhB.104.1001E
C.A. Friehe J.C. La Rue F.H. Champagne C.H. Gibson G.F. Dreyer Effects of temperature and humidity fluctuations on the optical refractive index in the marine boundary layer J. Opt. Soc. Am. A 1975 65 1502 1511 1975OSAJ..65.1502F
H. Gerçekcioğlu A.A. Abbas H.H. Göktaş Flat-topped Gaussian laser beam scintillation in weakly turbulent marine atmospheric medium Opt. Commun. 2017 399 24 27 2017OptCo.399..24G
I.S. Gradshteyn I.M. Ryzhik Table of Integrals, Series, and Products 2007 New York Academic press
K.J. Grayshan F.S. Vetelino C.Y. Young A marine atmospheric spectrum for laser propagation Waves. Random. Complex. Media 2008 18 173 184 2008WRCM..18.173G
M. Henriksson L. Sjöqvist D. Seiffer N. Wendelstein E. Sucher Laser beam propagation experiments along and across a jet engine plume Proc. SPIE 2008 7115 96 105
Z. Hricha M. Yaalou A. Belafhal Intensity characteristics of double-half inverse Gaussian hollow beams through turbulent atmosphere Opt. Quant. Electron. 2020 52 1 8
Z. Hricha M. Lazrek M. Yaalou A. Belafhal Propagation of vortex cosine-hyperbolic-Gaussian beams in atmospheric turbulence Opt. Quant. Electron. 2021 53 383 398
F. Khannous A. Belafhal A new study of turbulence effects in the marine environment on the intensity distributions of flat-topped Gaussian beams Optik 2016 127 8194 8202 2016Optik.127.8194K
F. Khannous A. Belafhal A new atmospheric spectral model for the marine environment Optik 2018 153 86 94 2018Optik.153..86K
Khannous, F., Chib, S., Belafhal, A.: Intensity characteristics of hypergeometric-gaussian type II beams in maritime turbulence, Opt. Quantum Electron., 55, (2023).
O. Korotkova S. Sahin E. Shchepakina Multi-Gaussian Schell-model beams J. Opt. Soc. Am. A 2012 29 2159 2164 2012JOSAA.29.2159K
O. Korotkova Random Light Beams: Theory and Applications 2014 Boca Raton CRC Press
H. Li J. Zhou Propagation of Gaussian Schell-model array beams through a jet engine exhaust Opt. Photonics. Journal. 2023 13 47 61 2023OPJ..13..47L
Z. Mei O. Korotkova Random sources generating ring-shaped beams Opt. Lett. 2013 38 91 93 2013OptL..38..91M
H. Nabil A. Balhamri A. Belafhal Propagation of the Laguerre–Gaussian correlated Shell-model beams through a turbulent jet engine exhaust Opt. Quant. Electron. 2022 54 231 249
H. Nabil A. Balhamri A. Belafhal Propagation of Bessel–Gaussian Shell-model beam through a jet engine exhaust turbulence Opt. Quant. Electron. 2022 54 332 352
H. Nabil A. Balhamri A. Belafhal Partially coherent laser beams propagating in jet engine exhaust induced turbulence Opt. Quant. Electron. 2022 54 404 427
H. Nabil M. Bayraktar A. Balhamri A. Belafhal A study of effects of a turbulent jet engine exhaust on partially coherent Laguerre–Gaussian Schell model vortex beam Optik 2023 272 170360 170380 2023Optik.272q0360N
H. Nabil A. Balhamri M. Bayraktar A. Belafhal Propagation characteristics of a partially coherent Gaussian Schell-model array vortex beam in the joint turbulence effect of a jet engine and atmosphere Ann. Phys. 2023 535
Saad, F., Benzehoua, H., Belafhal, A.: Propagation behavior of a new generalized laser beam through marine environment, Opt. Quantum Electron. 56 (2023)
V.S. Sirazetdinov Experimental study and numerical simulation of laser beams propagation through the turbulent aerojet Appl. Opt. 2008 47 975 985 2008ApOpt.47.975S
L. Sjöqvist Laser beam propagation in jet engine plume environments: a review Proc. SPIE 2008 7115 67 81
C. Sun X. Lv B. Ma J. Zhang D. Deng W. Hong Statistical properties of partially coherent radially and azimuthally polarized rotating elliptical Gaussian beams in oceanic turbulence with anisotropy Opt. Express 2019 27 245 256 2019OExpr.27A.245S
F. Wang X. Liu Y. Yuan Y. Cai Experimental generation of partially coherent beams with different complex degrees of coherence Opt. Lett. 2013 38 1814 1816 2013OptL..38.1814W
W. Wen X. Zhang Laser beam quality of airy beam in the jet engine exhaust induced turbulence Atmosphere 2023 14 1374 2023Atmos.14.1374W
Y. Wu Y. Zhang Y. Zhu Average intensity and directionality of partially coherent model beams propagating in turbulent ocean J. Opt. Soc. Am. A 2016 33 1451 1458 2016JOSAA.33.1451W
F. Ye J. Xie S. Hong J. Zhang D. Deng Propagation properties of a controllable rotating elliptical Gaussian optical coherence lattice in oceanic turbulence Res. Phys. 2019 13
X. Yu J. Tu X. Wang L. Zhang D. Deng Statistical properties of a controllable rotating elliptical Gaussian Schell-model vortex optical coherence lattice Opt. Commun. 2021 499
Y. Yuan X. Liu J. Qu M. Yao Y. Gao Y. Cai Second-order statistical properties of a J0-correlated Schell-model beam in a turbulent atmosphere J. Quant. Spectrosc. Radiat. Transf. 2019 224 185 191 2019JQSRT.224.185Y
H.T. Yura Mutual coherence function of a finite cross section optical beam propagating in a turbulent medium Appl. Opt. 1972 11 1399 1406 1972ApOpt.11.1399Y
Y. Zhang T. Hou Q. Chang H. Chang J. Long P. Ma P. Zhou Propagation properties of Gaussian Schell-model beam array in the jet engine exhaust induced turbulence IEEE Photonics J. 2020 12 1 13 2023Nanop.12..1Z
Y. Zhang Y. Deng T. Hou P. Ma R. Su P. Zhou The combined effect of jet and atmospheric turbulence on the propagation of airborne partially coherent array beams Ann. Phys. 2022 534 4443996
Y. Zhang L. Shan Y. Li L. Yu Effects of moderate to strong turbulence on the Hankel Bessel-Gaussian pulse beam with orbital angular momentum in the marine-atmosphere Opt. Express 2017 25 33469 33479 2017OExpr.2533469Z
Z. Zhu L. Liu F. Wang Y. Cai Evolution properties of a Laguerre–Gaussiancorrelated Schell-model beam propagating in uniaxial crystals orthogonal to the optical axis J. Opt. Soc. Am. A 2015 32 374 380 2015JOSAA.32.374Z