Propagation evolution of Airy Gaussian vortex beam through right-handed and left-handed media

Jin Long; Zhang Xingqiang; Xiong Yongchen; Fu Yanhua

doi:10.3788/IRLA201847.1006007

Based on light transfer matrix and generalized Huygens-Fresnel optical diffraction formula, the propagation evolution of Airy Gaussian vortex beam's normalized intensity distribution on emergent surface, side transmission view in periodic slab system contained right-handed and double negative material (DNM) were explored. Research shows that the original Airy Gaussian vortex beam intensity can be restored immaculately by using periodic slab system contained negative index material as long as the negative refractive index abs (nl)=nr and each unit length R:L=1:1; while abs (nl)nr but R=L, both types of emerging beams had poor quality, and in order to achieve beam reconstruction, the larger abs (nl) was, the longer DNM unit length was needed, and vice versa. Relation between DNM unit length and nl was thoroughly studied as well. It is expected that the relevant conclusions could provide important reference value for extension applications of optical control and communication transmission technique of the Airy Gaussian vortex beam propagating in the periodic and quasi-periodic metamaterials structure.

Propagation evolution of Airy Gaussian vortex beam through right-handed and left-handed media

1. Department of Basic Science,Hubei University of Automotive Technology,Shiyan 442002,China

Received Date: 2018-05-05

Rev Recd Date: 2018-06-03

Publish Date: 2018-10-25

Key words:

Abstract: Based on light transfer matrix and generalized Huygens-Fresnel optical diffraction formula, the propagation evolution of Airy Gaussian vortex beam's normalized intensity distribution on emergent surface, side transmission view in periodic slab system contained right-handed and double negative material (DNM) were explored. Research shows that the original Airy Gaussian vortex beam intensity can be restored immaculately by using periodic slab system contained negative index material as long as the negative refractive index abs (nl)=nr and each unit length R:L=1:1; while abs (nl)nr but R=L, both types of emerging beams had poor quality, and in order to achieve beam reconstruction, the larger abs (nl) was, the longer DNM unit length was needed, and vice versa. Relation between DNM unit length and nl was thoroughly studied as well. It is expected that the relevant conclusions could provide important reference value for extension applications of optical control and communication transmission technique of the Airy Gaussian vortex beam propagating in the periodic and quasi-periodic metamaterials structure.

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Propagation evolution of Airy Gaussian vortex beam through right-handed and left-handed media

doi: 10.3788/IRLA201847.1006007

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