1988
DOI: 10.1103/physrevlett.61.2445
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Experimental Observation of the Fundamental Dark Soliton in Optical Fibers

Abstract: We present evidence of soliton propagation by 185-fsec dark pulses at a wavelength of 0.62 /zm in a 1.4-m length of single-mode optical fiber. Our experiments utilize specially shaped, antisymmetric input pulses, which closely correspond to the form of the fundamental dark soliton. At appropriate power levels the dark pulses propagate without broadening. Our measurements are in quantitative agreement with numerical solutions to the nonlinear Schrodinger equation and constitute the first clear observation of th… Show more

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Cited by 352 publications
(108 citation statements)
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“…In the defocusing regime, the 1D NLSE has dark or gray soliton solutions. These solutions have also been experimentally observed [18,19], but the influence of these coherent structures on the statistics of systems of nonlinear random waves is not known.Some interesting approaches based on WT theory for studying the probability density function (PDF) of the 1D NLSE in the weakly nonlinear regime have been made [20]; however, as discussed in Ref.[21], the WT theory does not provide an appropriate framework for investigating the statistical phenomena described by integrable wave equations, especially in a strongly nonlinear regime. The theoretical analysis of these phenomena enters within the framework of an emerging field of research introduced by Zakharov under the appellation of "integrable turbulence" [21][22][23].…”
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confidence: 97%
“…In the defocusing regime, the 1D NLSE has dark or gray soliton solutions. These solutions have also been experimentally observed [18,19], but the influence of these coherent structures on the statistics of systems of nonlinear random waves is not known.Some interesting approaches based on WT theory for studying the probability density function (PDF) of the 1D NLSE in the weakly nonlinear regime have been made [20]; however, as discussed in Ref.[21], the WT theory does not provide an appropriate framework for investigating the statistical phenomena described by integrable wave equations, especially in a strongly nonlinear regime. The theoretical analysis of these phenomena enters within the framework of an emerging field of research introduced by Zakharov under the appellation of "integrable turbulence" [21][22][23].…”
mentioning
confidence: 97%
“…The shape and size of the dip is given by the interplay of mass and nonlinearity. Because of the universality of the mechanisms necessary to their formation, dark solitons have been observed in a wide variety of systems ranging from Bose-Einstein condensates of cold atoms [1][2][3], optical fibers [4], to thin magnetic films [5]. Interestingly, dark solitons have also been observed in nonlinear open-dissipative systems, in particular, in semiconductor microcavities [6][7][8][9] and are attracting great interest in view of photonic applications [10].…”
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confidence: 99%
“…This presence of a CW power pedestal [5,27] would affect the time-average excitation properties, however, narrow dark solitons can be excited on top of pulses with a large dispersion length compared to the notch waist , [29,30] enabling the independent control of the average power and the realization of anti-bullets under experimentally feasible conditions. An…”
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confidence: 99%
“…A train of broad optical pulses, each containing a π phase-discontinuity at the peak of the narrow notch, can be generated by spectral filtering [29,30]. Spatial (bright) and temporal (dark) soliton requirements for average and peak .…”
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confidence: 99%