Soliton-induced relativistic-scattering and amplification

E. Rubino; A. Lotti; F. Belgiorno; S. L. Cacciatori; A. Couairon; U. Leonhardt; D. Faccio

doi:10.1038/srep00932

Soliton-induced relativistic-scattering and amplification

E. Rubino
, A. Lotti
, F. Belgiorno
, S. L. Cacciatori
, A. Couairon
, U. Leonhardt
, D. Faccio

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

Abstract

Solitons are of fundamental importance in photonics due to applications in optical data transmission and also as a tool for investigating novel phenomena ranging from light generation at new frequencies and wave-trapping to rogue waves. Solitons are also moving scatterers: they generate refractive index perturbations moving at the speed of light. Here we found that such perturbations scatter light in an unusual way: they amplify light by the mixing of positive and negative frequencies, as we describe using a first Born approximation and numerical simulations. The simplest scenario in which these effects may be observed is within the initial stages of optical soliton propagation: a steep shock front develops that may efficiently scatter a second, weaker probe pulse into relatively intense positive and negative frequency modes with amplification at the expense of the soliton. Our results show a novel all-optical amplification scheme that relies on soliton induced scattering.

Original language	English
Article number	932
Journal	Scientific Reports
Volume	2
DOIs	https://doi.org/10.1038/srep00932
Publication status	Published - 1 Dec 2012

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10.1038/srep00932

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title = "Soliton-induced relativistic-scattering and amplification",

abstract = "Solitons are of fundamental importance in photonics due to applications in optical data transmission and also as a tool for investigating novel phenomena ranging from light generation at new frequencies and wave-trapping to rogue waves. Solitons are also moving scatterers: they generate refractive index perturbations moving at the speed of light. Here we found that such perturbations scatter light in an unusual way: they amplify light by the mixing of positive and negative frequencies, as we describe using a first Born approximation and numerical simulations. The simplest scenario in which these effects may be observed is within the initial stages of optical soliton propagation: a steep shock front develops that may efficiently scatter a second, weaker probe pulse into relatively intense positive and negative frequency modes with amplification at the expense of the soliton. Our results show a novel all-optical amplification scheme that relies on soliton induced scattering.",

author = "E. Rubino and A. Lotti and F. Belgiorno and Cacciatori, \{S. L.\} and A. Couairon and U. Leonhardt and D. Faccio",

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T1 - Soliton-induced relativistic-scattering and amplification

AU - Rubino, E.

AU - Lotti, A.

AU - Belgiorno, F.

AU - Cacciatori, S. L.

AU - Couairon, A.

AU - Leonhardt, U.

AU - Faccio, D.

PY - 2012/12/1

Y1 - 2012/12/1

N2 - Solitons are of fundamental importance in photonics due to applications in optical data transmission and also as a tool for investigating novel phenomena ranging from light generation at new frequencies and wave-trapping to rogue waves. Solitons are also moving scatterers: they generate refractive index perturbations moving at the speed of light. Here we found that such perturbations scatter light in an unusual way: they amplify light by the mixing of positive and negative frequencies, as we describe using a first Born approximation and numerical simulations. The simplest scenario in which these effects may be observed is within the initial stages of optical soliton propagation: a steep shock front develops that may efficiently scatter a second, weaker probe pulse into relatively intense positive and negative frequency modes with amplification at the expense of the soliton. Our results show a novel all-optical amplification scheme that relies on soliton induced scattering.

AB - Solitons are of fundamental importance in photonics due to applications in optical data transmission and also as a tool for investigating novel phenomena ranging from light generation at new frequencies and wave-trapping to rogue waves. Solitons are also moving scatterers: they generate refractive index perturbations moving at the speed of light. Here we found that such perturbations scatter light in an unusual way: they amplify light by the mixing of positive and negative frequencies, as we describe using a first Born approximation and numerical simulations. The simplest scenario in which these effects may be observed is within the initial stages of optical soliton propagation: a steep shock front develops that may efficiently scatter a second, weaker probe pulse into relatively intense positive and negative frequency modes with amplification at the expense of the soliton. Our results show a novel all-optical amplification scheme that relies on soliton induced scattering.

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SN - 2045-2322

VL - 2

JO - Scientific Reports

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M1 - 932

ER -

Soliton-induced relativistic-scattering and amplification

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