Self-phase modulation spectral broadening in two-dimensional spatial solitons: Toward three-dimensional spatiotemporal pulse-train solitons

Oren Lahav; Hassid Gurgov; Pavel Sidorenko; Or Peleg; Liad Levi; Avner Fleischer; Oren Cohen

doi:https://doi.org/10.1364/OL.37.005196

Self-phase modulation spectral broadening in two-dimensional spatial solitons: Toward three-dimensional spatiotemporal pulse-train solitons

Oren Lahav, Hassid Gurgov, Pavel Sidorenko, Or Peleg, Liad Levi, Avner Fleischer, Oren Cohen

Technion - Israel Institute of Technology

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

Abstract

We demonstrate self-phase modulation (SPM) spectral broadening in two-dimensional solitons in homogeneous media using two different schemes. In the active mode, a train of pulses are collectively trapped and form a spatial soliton through a photorefractive, slowly responding, and electronically controlled self-focusing nonlinearity, and each pulse experiences spectral broadening by the fast SPM nonlinearity. In the passive mode, the pulse-train beam is guided in a waveguide that is optically induced by a continuous-wave thermal spatial soliton. The soliton formation increased the normalized spectral broadening factor from 0.5% up to 197%. This experiment presents significant progress toward the experimental demonstration of three-dimensional spatiotemporal pulse-train solitons.

Original language	English
Pages (from-to)	5196-5198
Number of pages	3
Journal	Optics Letters
Volume	37
Issue number	24
DOIs	https://doi.org/10.1364/OL.37.005196
State	Published - 15 Dec 2012

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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https://doi.org/10.1364/OL.37.005196

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title = "Self-phase modulation spectral broadening in two-dimensional spatial solitons: Toward three-dimensional spatiotemporal pulse-train solitons",

abstract = "We demonstrate self-phase modulation (SPM) spectral broadening in two-dimensional solitons in homogeneous media using two different schemes. In the active mode, a train of pulses are collectively trapped and form a spatial soliton through a photorefractive, slowly responding, and electronically controlled self-focusing nonlinearity, and each pulse experiences spectral broadening by the fast SPM nonlinearity. In the passive mode, the pulse-train beam is guided in a waveguide that is optically induced by a continuous-wave thermal spatial soliton. The soliton formation increased the normalized spectral broadening factor from 0.5% up to 197%. This experiment presents significant progress toward the experimental demonstration of three-dimensional spatiotemporal pulse-train solitons.",

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T1 - Self-phase modulation spectral broadening in two-dimensional spatial solitons

T2 - Toward three-dimensional spatiotemporal pulse-train solitons

AU - Lahav, Oren

AU - Gurgov, Hassid

AU - Sidorenko, Pavel

AU - Peleg, Or

AU - Levi, Liad

AU - Fleischer, Avner

AU - Cohen, Oren

PY - 2012/12/15

Y1 - 2012/12/15

N2 - We demonstrate self-phase modulation (SPM) spectral broadening in two-dimensional solitons in homogeneous media using two different schemes. In the active mode, a train of pulses are collectively trapped and form a spatial soliton through a photorefractive, slowly responding, and electronically controlled self-focusing nonlinearity, and each pulse experiences spectral broadening by the fast SPM nonlinearity. In the passive mode, the pulse-train beam is guided in a waveguide that is optically induced by a continuous-wave thermal spatial soliton. The soliton formation increased the normalized spectral broadening factor from 0.5% up to 197%. This experiment presents significant progress toward the experimental demonstration of three-dimensional spatiotemporal pulse-train solitons.

AB - We demonstrate self-phase modulation (SPM) spectral broadening in two-dimensional solitons in homogeneous media using two different schemes. In the active mode, a train of pulses are collectively trapped and form a spatial soliton through a photorefractive, slowly responding, and electronically controlled self-focusing nonlinearity, and each pulse experiences spectral broadening by the fast SPM nonlinearity. In the passive mode, the pulse-train beam is guided in a waveguide that is optically induced by a continuous-wave thermal spatial soliton. The soliton formation increased the normalized spectral broadening factor from 0.5% up to 197%. This experiment presents significant progress toward the experimental demonstration of three-dimensional spatiotemporal pulse-train solitons.

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M3 - مقالة

C2 - 23258050

SN - 0146-9592

VL - 37

SP - 5196

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JO - Optics Letters

JF - Optics Letters

IS - 24

ER -

Self-phase modulation spectral broadening in two-dimensional spatial solitons: Toward three-dimensional spatiotemporal pulse-train solitons

Abstract

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