Microstructured optical fibers based on As2Se3 glass may be designed to have an in-plane photonic bandgap, and thereby support modes with zero propagation constant and zero group velocity [1]. It has been shown that such structures will support gap solitons which by way of Raman scattering will be driven towards the zerovelocity state [2,3]. An important question in connection with slow-light propagation is the influence of waveguide imperfections, which typically leads to a strong scattering of the slow light as the group velocity tends to zero. Theoretical investigations of this subject have so far focused on the experimentally realized case of planar photonic bandgap waveguides, where the imperfections are present on a subwavelength scale given by the lattice periodicity. In microstructured fibers, however, the deformation spectrum can be expected to be of an entirely different nature, with long-period perturbations playing a dominant role. The purpose of this work is to investigate how such long-period perturbations will affect the propagation of slow-mode optical solitons.
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机译:可以将基于As 2 Se 3 玻璃的微结构光纤设计为具有面内光子带隙,从而支持传播常数为零且群速度为零的模式[1] ]。已经表明,这种结构将支持间隙孤子,该间隙孤子通过拉曼散射将被驱动向零速度状态[2,3]。与慢速光传播有关的一个重要问题是波导缺陷的影响,当群速度趋于零时,通常会导致慢速光的强烈散射。迄今为止,该主题的理论研究一直集中在实验实现的平面光子带隙波导的情况下,其中缺陷以晶格周期性给出的亚波长范围存在。但是,在微结构纤维中,可以预期变形谱具有完全不同的性质,其中长期扰动起主要作用。这项工作的目的是研究这种长期扰动将如何影响慢模光学孤子的传播。
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