Interactions of incoherent localized beams in a photorefractive medium

Zhang, Yiqi; Belić, Milivoj R.; Zheng, Huaibin; Chen, Hạixia; Xu, Jianeng

doi:10.1364/josab.31.002258

Cited by 2 publications

(2 citation statements)

References 40 publications

(48 reference statements)

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“…In Figure a, the superhoneycomb lattice induced in the SBN crystal is shown. We would like to note that we take the SBN crystal as our target system; however, our research can be simply extended to other systems, e.g., femto‐second laser direct‐writing waveguide arrays, cold atoms, atomic vapors, and exciton‐poaritons, to name a few.…”

Section: Superhoneycomb Lattice Band Structure and Statesmentioning

confidence: 99%

Conical Diffraction from Approximate Dirac Cone States in a Superhoneycomb Lattice

et al. 2019

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Superhoneycomb lattice is an edge-centered honeycomb lattice that represents a hybrid fermionic and bosonic system. It contains pseudospin-1/2 and pseudospin-1 Dirac cones, as well as a flat band in its band structure. In this paper, we cut the superhoneycomb lattice along short-bearded boundaries and obtain the corresponding band structure. The states very close to the Dirac points represent approximate Dirac cone states that can be used to observe conical diffraction during light propagation in the lattice. In comparison with the previous literature, this research is carried out using the continuous model, which brings new results and is simple, direct, accurate, and computationally efficient.

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Section: Superhoneycomb Lattice Band Structure and Statesmentioning

confidence: 99%

Conical Diffraction from Approximate Dirac Cone States in a Superhoneycomb Lattice

et al. 2019

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“…The interaction of spatial solitons has attracted increasing attention in the last few years [1][2][3][4][5][6][7][8][9][10], as it has the potential for building logical operators [11] and in all-optical switching [12,13]. Thus far, many kinds of optical spatial solitons have been reported, such as steady-state spatial screening solitons [14], screening-photovoltaic spatial solitons [15], photovoltaic lattice solitons (LSs) [16], multi-peaked gap solitons [17], two-dimensional gap-solitons [18], and rotary dissipative spatial solitons [19].…”

Section: Introductionmentioning

confidence: 99%

Influence of lattice defects on the coherent interaction of photovoltaic lattice solitons

Chen

Luo

et al. 2015

J. Opt.

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The influence of an optically induced waveguide lattice with a defect on the coherent interaction of one-dimensional lattice solitons (LSs) formed via the photovoltaic photorefractive effect is investigated by employing numerical simulations. The results show that the uniform lattice can keep the neighboring LSs propagating with constant spacing and can affect the energy transfer between them. Further research has shown that the energy transfer can be effectively controlled by adjusting the relative phase difference between neighboring LSs and by introducing a defect in the waveguide lattice.

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Interactions of incoherent localized beams in a photorefractive medium

Cited by 2 publications

References 40 publications

Conical Diffraction from Approximate Dirac Cone States in a Superhoneycomb Lattice

Conical Diffraction from Approximate Dirac Cone States in a Superhoneycomb Lattice

Influence of lattice defects on the coherent interaction of photovoltaic lattice solitons

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