Infrared and Laser Engineering, Volume. 50, Issue 9, 20210242(2021)
Selection of full Poincaré beams with higher robustness in turbulent atmosphere (Invited)
[1] Y W Zhai, S Y Fu, J Q Zhang, et al. Turbulence aberration correction for vector vortex beams using deep neural networks on experimental data. Optics Express, 28, 7515-7527(2020).
[2] Chunqing Gao, Shikun Zhang, Shiyao Fu, et al. Adaptive optics wavefront correction techniques of vortex beams. Infrared and Laser Engineering, 46, 0201001(2017).
[3] H Rubinsztein-Dunlop, A Forbes, M V Berry, et al. Roadmap on structured light. Journal of Optics, 19, 013001(2016).
[4] M Lavery, C Peuntinger, K Günthner, et al. Free-space propagation of high-dimensional structured optical fields in an urban environment. Science Advances, 3, e1700552(2017).
[5] A E Willner, Y X Ren, G D Xie, et al. Recent advances in high-capacity free-space optical and radio-frequency communications using orbital angular momentum multiplexing. Philosophical Transactions A, 375, 20150439(2017).
[6] A M Beckley, T G Brown, M A Alonso. Full Poincaré beams. Optics Express, 18, 10777-10785(2010).
[7] W Chen, J W Haus, Q W Zhan. Propagation of vector vortex beams through a turbulent atmosphere. Optics Express, 17, 17829-17836(2009).
[8] M A Cox, C Rosales-Guzmán, M Lavery, et al. On the resilience of scalar and vector vortex modes in turbulence. Optics Express, 24, 18105-18113(2016).
[9] J Y Yu, Y Huang, F Wang, et al. Scintillation properties of a partially coherent vector beam with vortex phase in turbulent atmosphere. Optics Express, 27, 26676-26688(2019).
[10] C Wei, D Wu, C H Liang, et al. Experimental verification of significant reduction of turbulence-induced scintillation in a full poincaré beam. Optics Express, 23, 24331-24341(2015).
[11] L Priyanka, P Senthilkumaran, K Khare. Designer vector beams maintaining a robust intensity profile on propagation through turbulence. Physical Review A, 98, 023831(2018).
[12] P Lochab, P Senthilkumaran, K Khare. Propagation of converging polarization singular beams through atmospheric turbulence. Applied Optics, 58, 6335-6345(2019).
[13] X N Yi, Y C Liu, X H Ling, et al. Hybrid-order Poincaré sphere. Physics Review A, 91, 023801(2015).
[14] G Milione, H I Sztul, D A Nolan, et al. Higher-order Poincaré sphere, Stokes parameters, and the angular momentum of light. Physical Review Letters, 107, 053601(2011).
[15] Xiangkong Zhan, Zhengyong Li, Yi Zhang, et al. Radially polarized beam restructuring based on Stokes-vector measurement and interferometry. Infrared and Laser Engineering, 46, 0427002(2017).
[16] A N Kolmogorov. The local structure of turbulence in incompressible viscous fluid for very large reynolds numbers. Proceedings of the Royal Society A: Mathematical, 434, 9-13(1991).
[17] G D Xie, Y X Ren, H Huang, et al. Phase correction for a distorted orbital angular momentum beam using a Zernike polynomials-based stochastic-parallel-gradient-descent algorithm. Optics Letters, 40, 1197-1200(2015).
[18] S Y Fu, Y W Zhai, J Q Zhang, et al. Universal orbital angular momentum spectrum analyzer for beams. PhotoniX, 1, 19(2020).
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Xueting Liu, Yanwang Zhai, Shiyao Fu, Chunqing Gao. Selection of full Poincaré beams with higher robustness in turbulent atmosphere (Invited)[J]. Infrared and Laser Engineering, 2021, 50(9): 20210242
Category: Special issue-Manipulation on optical vortex and its sensing application
Received: Apr. 13, 2021
Accepted: --
Published Online: Oct. 28, 2021
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