Accelerating Airy wave packets in the presence of quadratic and cubic dispersion

Besieris, Ioannis M.; Shaarawi, Amr M.

doi:10.1103/physreve.78.046605

Cited by 86 publications

(41 citation statements)

References 7 publications

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“…This is explained by the fact that the radiation component of the field generated by the fission tends to form an Airy-like pattern under the action of TOD [23], which plays the role of a potential structure binding the soliton chain. To confirm the universal character of the dynamics of the soliton NC under the action of TOD, Fig.…”

Section: The Model and The Main Resultsmentioning

confidence: 96%

Introduction of optical Newton cradle model for understanding the N-solitons fission process under the action of higher order dispersion

et al. 2013

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A mechanism of creating a Newton's cradle (NC) in the form of a chain of solitons is proposed for understanding fission of higher-order soliton in optical fibers caused by higher-order dispersion. After the transformation of the initial Nsoliton into a chain of fundamental quasi-solitons, the tallest one travels along the chain through elastic collisions with other solitons, and then escapes, while the other solitons remain in a bound state. Multiple releases of solitons take place if N is sufficiently large. The NC effect is robust against inclusion of the Raman and self-steepening terms.

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Section: The Model and The Main Resultsmentioning

confidence: 96%

Introduction of optical Newton cradle model for understanding the N-solitons fission process under the action of higher order dispersion

et al. 2013

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“…The resulting Airy pulses can propagate with acceleration and minimum shape distortion over several dispersion lengths in media with quadratic or cubic dispersion [23]. These unique waveforms have so far found application for generating dispersion-and diffraction-resisting optical bullets [24], optical solitons [25], and supercontinua [26].…”

Section: Introductionmentioning

confidence: 99%

Reflection and refraction of an Airy beam at a dielectric interface

Chremmos

Efremidis

2012

J. Opt. Soc. Am. A

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Reflection and refraction of a finite-power Airy beam at the interface between two dielectric media are investigated analytically and numerically. The formulation takes into account the paraxial nature of the optical beams to derive convenient field evolution equations in coordinate frames moving along Snell's refraction and reflection axes. Through numerical simulations, the self-accelerating dynamics of the Airy-like refracted and reflected beams are observed. Of special interest are the cases of critical incidence at Brewster and total-internal-reflection (TIR) angles. In the former case, we find that the reflected beam achieves self-healing, despite the severe suppression of a part of its spectrum, while, in the latter case, the beam remains nearly unaffected except for the GoosHänchen shift. The self-accelerating quality persists even if the beam is trapped by multiple TIRs inside a dielectric film. The grazing incidence of an Airy beam at the interface between two media with close refractive indices is also investigated, revealing that the interface can act as a filter depending on the beam scale and tilt. We finally consider reverse refraction and perfect imaging of an Airy beam into a left-handed medium.

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“…However, it is possible to obtain a finite-energy version of the ideal Airy pulse by modulating it with a time exponential function on the initial plane z 0 [2,3]. The analysis of a finite-energy Airy pulse considering the effects of second-and third-order dispersion was first made in [3] and subsequently in [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

“…The latter would be of interest for accelerating waves in fiber-optical waveguides, as well for retaining the integrity of the main lobe for large ranges. Besieris and Shaarawi [3] recognized that an exact accelerating and weakly dispersive Airy wave packet solution was possible for the more general case where both second-and third-order dispersion were taken into account. There exist physical situations where one or the other, as well as both, of these effects predominate.…”

Section: Introductionmentioning

confidence: 99%

Propagation of time-truncated Airy-type pulses in media with quadratic and cubic dispersion

et al. 2015

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In this paper, we describe analytically the propagation of Airy-type pulses truncated by a finite-time aperture when second- and third-order dispersion effects are considered. The mathematical method presented here, which is based on the superposition of exponentially truncated Airy pulses, is very effective and allows us to avoid the use of time-consuming numerical simulations. We analyze the behavior of the time-truncated ideal Airy pulse and also the interesting case of a time-truncated Airy pulse with a "defect" in its initial profile, which reveals the self-healing property of this kind of pulse solution.

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Accelerating Airy wave packets in the presence of quadratic and cubic dispersion

Cited by 86 publications

References 7 publications

Introduction of optical Newton cradle model for understanding the N-solitons fission process under the action of higher order dispersion

Introduction of optical Newton cradle model for understanding the N-solitons fission process under the action of higher order dispersion

Reflection and refraction of an Airy beam at a dielectric interface

Propagation of time-truncated Airy-type pulses in media with quadratic and cubic dispersion

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