Numerical study of lateral displacements of Gaussian beams reflected from weakly absorbing media near the Brewster dip and reflected from strongly absorbing media

Using the angular spectrum method, we numerically investigate the reflection of a Gaussian beam reflected from weakly absorbing media near the Brewster dip and from strongly absorbing media. Numerical simulations are presented and the field values are computed as well as the time-averaged power dens...

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Bibliographic Details
Published inJournal of optics. A, Pure and applied optics Vol. 11; no. 10; p. 105701
Main Authors Wang, Yan, Liu, Yanhong, Xu, Jun, Zhang, Huifang, Bai, Lihua, Xiao, Yueyu, Yan, Jinkui, Zhang, Xianmei
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.10.2009
Institute of Physics
Subjects
Absorption
Beams (radiation)
Density
Dipping
Edge and boundary effects; reflection and refraction
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Gaussian beams (optics)
Mathematical models
Media
Optics
Physics
Propagation modes
Wave optics
Wave propagation, transmission and absorption
Gaussian beam
Absorbent material
Electromagnetic wave propagation
Digital simulation
Theoretical study
absorbing media
Electromagnetic wave reflection
Numerical method
Propagation mode
Brewster dip
Gaussian beams
lateral displacement
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Summary:Using the angular spectrum method, we numerically investigate the reflection of a Gaussian beam reflected from weakly absorbing media near the Brewster dip and from strongly absorbing media. Numerical simulations are presented and the field values are computed as well as the time-averaged power densities. Besides, the number of effective propagation modes is defined. Apart from that, beamsplitting is presented and is interpreted by the missing of the propagation mode when the light is reflected from a weakly absorbing medium near the Brewster dip. Beamsplitting, however, is not observed, therefore both beam shift and angular shift have been calculated when the light is reflected from a strongly absorbing medium. The conditions for Artmann's formula to be valid in the case of the Brewster dip are discussed. Our results do not support the validity of Artmann's formula applied to the case when a Gaussian beam is reflected from weakly absorbing media near the Brewster dip, but indicate that Artmann's formula is valid and very good for the case of a beam reflected from strongly absorbing media.
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ISSN:1464-4258
1741-3567
DOI:10.1088/1464-4258/11/10/105701