Shifting bright spatial solitons in LiNbO_3

Gao, Cunyuan; Xu, Jü; Qiu, Jichuan; Liu, S. W.; Gu, Feng

doi:10.1364/ol.37.003702

Cited by 5 publications

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References 15 publications

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“…Quadratic spatial solitons generated in periodically poled LiNbO 3 , KTiOPO 4 , and KTiOAsO 4 in the picosecond regime have been investigated. [14][15][16][17][18][19][20] In this article, quadratic spatial solitons generated in periodically poled lithium tantalite (PPLT) in the femtosecond regime are investigated. By using only a fundamental frequency beam as an input, we are able to observe a single soliton and spatially anisotropic multiple solitons.…”

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confidence: 99%

Quadratic spatial solitons generated in periodically poled lithium tantalite

et al. 2013

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Abstract. The properties of quadratic spatial solitons generated in periodically poled lithium tantalite in the femtosecond regime are investigated. By using only a fundamental frequency beam as the input to excite quadratic spatial solitons, single and spatially anisotropic multiple solitons are generated. Our experiments demonstrate that the number of solitons is dependent on the input power. In the experiment, beam narrowing occurs first, leading to single-soliton generation. The threshold for multiple solitons is around 1.5 mW. The number of solitons does not increase indefinitely with input power. Multiple soliton generation only occurs in the input power range of 1.5 to 6.3 mW. The number of solitons decreases to 1 when the input power is 6.3 mW. The temporal and spectral characteristics of the spatial solitons are measured by using the GRENOUILLE technique. © IntroductionWith the development of high power ultrafast lasers, quadratic nonlinear crystals have become widely used in nonlinear optics, and the quadratic spatial soliton is one of the most intriguing nonlinear effects.1-10 One of the unique features of quadratic solitons is that they consist of all of the beams strongly coupled together by the second-order nonlinearity. Second-harmonic generation (SHG) processes can result in generation of quadratic spatial soliton. With their particlelike behavior in interactions and collisions, spatial solitons have the potential to be used for all-optical data processing, pattern recognition, and parallel information storage.

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