The Effect of Air Turbulence on Vortex Beams in Nonlinear Propagation

Zhu, Dongmei; Li, Chunhua; Sun, Xiaodong; Liu, Yali; Zhang, Yuqi; Gao, Hui

doi:10.3390/s23041772

Cited by 4 publications

(2 citation statements)

References 51 publications

(56 reference statements)

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“…Results from these studies suggest that the spiral phase structure and the OAM provide vortex beams with additional resilience against complex refraction, such as turbulence and high order aberrations, as well as random particle scattering and absorption. Furthermore, if we treat the conventional Gaussian beam as a vortex beam with topological charge zero, then we can reach a more general conclusion that a higher topological charge normally suggests more resilience to perturbations in the beam path which can be described by multiple metrics including the fluctuation of intensity [13][14][15], transmittance [16], beam wandering [17] and so on. However, metrics regarding the basic shape properties of the beams have not been reported so far.…”

Section: Introductionmentioning

confidence: 97%

Long range propagation of optical vortex beams in atmospheric turbulence

Zhang,

Li,

Chirinos

et al. 2024

Free-Space Laser Communications XXXVI

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Remote laser detection requires laser beam propagation through often unfavorable real-world atmospheric conditions. Turbulence is one of the main factors causing the beam to get distorted and lose its integrity and has direct implications on our ability to detect spectroscopic signatures remotely. One method to suppress turbulence effects is the use of vortex beams which have a spiral phase structure and carry the orbital angular momentum (OAM). Vortex beams are generally considered to be more robust against the turbulence effects compared to conventional Gaussian beams. However, the actual vortex beam performance in remote sensing is also heavily dependent on the exact mode of vortex beam family it belongs to. In this work, we simulate the propagation of beams to a distance of 100 meters under controlled turbulence and compared the performance of a conventional Gaussian beam to two different modes of vortex beams: Hypergeometric Gaussian (HyGG) and Laguerre Gaussian (LG) beams. Through detailed evaluation of the beam circularity as a quantitative metric for beam propagation under turbulence, we demonstrate that HyGG vortex beams exhibit improved resistance against turbulence when compared to conventional Gaussian beams and LG vortex beams. This work provides insights toward a more comprehensive understanding of how vortex beams benefit long-range remote detection and identifying new strategies for long propagation-range propagation of tailored laser beams.

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Section: Introductionmentioning

confidence: 97%

Long range propagation of optical vortex beams in atmospheric turbulence

Zhang,

Li,

Chirinos

et al. 2024

Free-Space Laser Communications XXXVI

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“…During propagation, the CAB can initially keep a low-intensity distribution, then abruptly converge to a focal point where the intensity is suddenly enhanced by orders of magnitude [25][26][27][28][29]. In recent years, vortex phase modulation has allowed for the extension of the CABs from single vortex CABs to double or multiple vortex CABs [30][31][32][33][34]. Therefore, combining the CAB and the segmented vortex phase is of great interest to facilitate more flexible control of the auto-focusing characteristics and local vortex of the beam.…”

Section: Introductionmentioning

confidence: 99%

Generation of auto-focusing vortex beam via segment vortex phase for imaging edge-enhancement

Lin,

Tao

2024

Phys. Scr.

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The auto-focusing beam based on the circular Airy beam and segmented vortex phase, termed circular Airy segmented vortex beam (CASVB), was generated. During propagation, the focusing properties of the CASVB can be flexibly tunable for multiple degrees of freedom. The results show that the segmentation type of the vortex phase are determined by the number and position of phase jumps, which results in the beam split. Moreover, the number and position of the CASVB gaps coincide with the number and position of the phase jumps. In addition, the edge images can be enhanced by combining the phase of the beam with the phase of the lens. Due to its adjustable number and position of gaps, the CASVB will likely give rise to potential applications in manipulating particles along different segmented intensity trajectories.

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