Boosting few-cycle soliton self-frequency shift using negative prechirp

Yuval Rosenberg; Jonathan Drori; David Bermudez; Ulf Leonhardt

doi:10.1364/OE.383014

Boosting few-cycle soliton self-frequency shift using negative prechirp

Yuval Rosenberg, Jonathan Drori, David Bermudez, Ulf Leonhardt

Department of Physics of Complex Systems

Weizmann Institute of Science

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

Abstract

Soliton self-frequency shifting of light pulses in fibers is used for versatile tunable light sources. Few-cycle pulses of high soliton number offer unique advantages, in particular the rate of Raman frequency shift is extremely fast. However, their dynamics is complicated, which makes the optimization of the frequency shifting difficult and sometimes counter-intuitive. We performed a systematic experimental study of the effects of initial prechirp for different pulse energies (for two different fibers). We found that a negative prechirp around C=-0.75 is the most effective (C being the chirp parameter). With such prechirping we managed to cross the severe OH absorption bands of nonlinear photonic crystal fibers. The mechanism behind the effectiveness of the prechirp appears to be the power distribution between the products of soliton fission.

Original language	English
Pages (from-to)	3107-3115
Number of pages	9
Journal	Optics Express
Volume	28
Issue number	3
DOIs	https://doi.org/10.1364/OE.383014
State	Published - 3 Feb 2020

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10.1364/OE.383014

Cite this

@article{82480a1080a744ac9557c49907118067,

title = "Boosting few-cycle soliton self-frequency shift using negative prechirp",

abstract = "Soliton self-frequency shifting of light pulses in fibers is used for versatile tunable light sources. Few-cycle pulses of high soliton number offer unique advantages, in particular the rate of Raman frequency shift is extremely fast. However, their dynamics is complicated, which makes the optimization of the frequency shifting difficult and sometimes counter-intuitive. We performed a systematic experimental study of the effects of initial prechirp for different pulse energies (for two different fibers). We found that a negative prechirp around C=-0.75 is the most effective (C being the chirp parameter). With such prechirping we managed to cross the severe OH absorption bands of nonlinear photonic crystal fibers. The mechanism behind the effectiveness of the prechirp appears to be the power distribution between the products of soliton fission.",

author = "Yuval Rosenberg and Jonathan Drori and David Bermudez and Ulf Leonhardt",

note = "European Research Council; Secretar{\'i}a de Educaci{\'o}n P{\'u}blica; Centro de Investigaci{\'o}n y de Estudios Avanzados del Instituto Polit{\'e}cnico Nacional; Israel Science Foundation (501100003977); and Murray B. Koffler Professorial Chair. We are most grateful to Rafael Probst and Yaron Silberberg for their help and encouragement. These authors contributed equally to this work: Yuval Rosenberg, Jonathan Drori",

year = "2020",

month = feb,

day = "3",

doi = "10.1364/OE.383014",

language = "الإنجليزيّة",

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T1 - Boosting few-cycle soliton self-frequency shift using negative prechirp

AU - Rosenberg, Yuval

AU - Drori, Jonathan

AU - Bermudez, David

AU - Leonhardt, Ulf

N1 - European Research Council; Secretaría de Educación Pública; Centro de Investigación y de Estudios Avanzados del Instituto Politécnico Nacional; Israel Science Foundation (501100003977); and Murray B. Koffler Professorial Chair. We are most grateful to Rafael Probst and Yaron Silberberg for their help and encouragement. These authors contributed equally to this work: Yuval Rosenberg, Jonathan Drori

PY - 2020/2/3

Y1 - 2020/2/3

N2 - Soliton self-frequency shifting of light pulses in fibers is used for versatile tunable light sources. Few-cycle pulses of high soliton number offer unique advantages, in particular the rate of Raman frequency shift is extremely fast. However, their dynamics is complicated, which makes the optimization of the frequency shifting difficult and sometimes counter-intuitive. We performed a systematic experimental study of the effects of initial prechirp for different pulse energies (for two different fibers). We found that a negative prechirp around C=-0.75 is the most effective (C being the chirp parameter). With such prechirping we managed to cross the severe OH absorption bands of nonlinear photonic crystal fibers. The mechanism behind the effectiveness of the prechirp appears to be the power distribution between the products of soliton fission.

AB - Soliton self-frequency shifting of light pulses in fibers is used for versatile tunable light sources. Few-cycle pulses of high soliton number offer unique advantages, in particular the rate of Raman frequency shift is extremely fast. However, their dynamics is complicated, which makes the optimization of the frequency shifting difficult and sometimes counter-intuitive. We performed a systematic experimental study of the effects of initial prechirp for different pulse energies (for two different fibers). We found that a negative prechirp around C=-0.75 is the most effective (C being the chirp parameter). With such prechirping we managed to cross the severe OH absorption bands of nonlinear photonic crystal fibers. The mechanism behind the effectiveness of the prechirp appears to be the power distribution between the products of soliton fission.

U2 - 10.1364/OE.383014

DO - 10.1364/OE.383014

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