Counterpropagating self-trapped beams in photorefractive crystals

M. Belić; Ph Jander; K. Motzek; A. Desyatnikov; D. Jović; A. Strinić; M. Petrović; C. Denz; F. Kaiser

doi:10.1088/1464-4266/6/5/005

Counterpropagating self-trapped beams in photorefractive crystals

M. Belić^*, Ph Jander, K. Motzek, A. Desyatnikov, D. Jović, A. Strinić, M. Petrović, C. Denz, F. Kaiser

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

Abstract

A time-dependent model for the formation of self-trapped optical beams in photorefractive media by counterpropagating laser beams is analysed. It is shown that dynamically the beams may form stable steady-state structures or display periodic and irregular temporal behaviour. Steady-state solutions of non-uniform cross section are found, representing a general class of self-trapped waveguides, that include counterpropagating spatial vector solitons as a particular case. Two critical curves are identified in the plane of parameters, the first one separating vector solitons from the stable bidirectional waveguides and the second one separating stable waveguides from the unstable ones. Dynamically stable rotating beam structures are discovered that have no analogues in the usual steady-state theory of spatial solitons.

Original language	English
Pages (from-to)	S190-S196
Journal	Journal of Optics B: Quantum and Semiclassical Optics
Volume	6
Issue number	5
DOIs	https://doi.org/10.1088/1464-4266/6/5/005
Publication status	Published - May 2004
Externally published	Yes

Keywords

Counterpropagating beams
Nonlinear optics
Photorefractive crystal
Transverse effects

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10.1088/1464-4266/6/5/005

Cite this

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title = "Counterpropagating self-trapped beams in photorefractive crystals",

abstract = "A time-dependent model for the formation of self-trapped optical beams in photorefractive media by counterpropagating laser beams is analysed. It is shown that dynamically the beams may form stable steady-state structures or display periodic and irregular temporal behaviour. Steady-state solutions of non-uniform cross section are found, representing a general class of self-trapped waveguides, that include counterpropagating spatial vector solitons as a particular case. Two critical curves are identified in the plane of parameters, the first one separating vector solitons from the stable bidirectional waveguides and the second one separating stable waveguides from the unstable ones. Dynamically stable rotating beam structures are discovered that have no analogues in the usual steady-state theory of spatial solitons.",

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T1 - Counterpropagating self-trapped beams in photorefractive crystals

AU - Belić, M.

AU - Jander, Ph

AU - Motzek, K.

AU - Desyatnikov, A.

AU - Jović, D.

AU - Strinić, A.

AU - Petrović, M.

AU - Denz, C.

AU - Kaiser, F.

PY - 2004/5

Y1 - 2004/5

N2 - A time-dependent model for the formation of self-trapped optical beams in photorefractive media by counterpropagating laser beams is analysed. It is shown that dynamically the beams may form stable steady-state structures or display periodic and irregular temporal behaviour. Steady-state solutions of non-uniform cross section are found, representing a general class of self-trapped waveguides, that include counterpropagating spatial vector solitons as a particular case. Two critical curves are identified in the plane of parameters, the first one separating vector solitons from the stable bidirectional waveguides and the second one separating stable waveguides from the unstable ones. Dynamically stable rotating beam structures are discovered that have no analogues in the usual steady-state theory of spatial solitons.

AB - A time-dependent model for the formation of self-trapped optical beams in photorefractive media by counterpropagating laser beams is analysed. It is shown that dynamically the beams may form stable steady-state structures or display periodic and irregular temporal behaviour. Steady-state solutions of non-uniform cross section are found, representing a general class of self-trapped waveguides, that include counterpropagating spatial vector solitons as a particular case. Two critical curves are identified in the plane of parameters, the first one separating vector solitons from the stable bidirectional waveguides and the second one separating stable waveguides from the unstable ones. Dynamically stable rotating beam structures are discovered that have no analogues in the usual steady-state theory of spatial solitons.

KW - Counterpropagating beams

KW - Nonlinear optics

KW - Photorefractive crystal

KW - Transverse effects

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Counterpropagating self-trapped beams in photorefractive crystals

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