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Adiabatic pulse propagation in a dispersion-increasing fiber is used to generate dual spectrally compressed peaks with tunable amplitudes. Our experimental results are in excellent agreements as compared to numerical calculations.
We demonstrate experimentally that laser amplitude and timing jitters can be improved when the laser pulse undergoes adiabatic spectral compression in a dispersion-increasing fiber.
Waveform dependence of laser spectral compression in a dispersion-increasing fiber is investigated. Experimentally, record-high spectral compression ratios of 35.3 and 41.7 are respectively achieved using a stretch-pulse mode-locked fiber laser and an all-normal dispersion laser.
The feasibility to achieve large-scale spectral compression of an all-normal dispersion fiber laser in a dispersion-increasing fiber is studied both numerically and experimentally. Experimentally, a record-high spectral compression ratio of 46.7 is achieved.
We demonstrate large-scale true adiabatic soliton spectral compression using a dispersion-increasing fiber in the 1.57 μm wavelength region. A record-high spectral compression ratio of 28.4 is experimentally achieved.
For the first time to our best knowledge, adiabatic soliton spectral compression is experimentally demonstrated in a dispersion-increasing fiber. Spectral compression ratio of 15.5 is obtained using 350 fs up-chirped pulse in the 1.5 µm.
A single line-by-line optical pulse shaper is used to experimentally generate and deliver 1.04 ps optical pulse train with 496 GHz repetition-rate over 25.33 km single-mode fiber without the need for dispersion-compensating fiber.
We experimentally demonstrate a spectral line-by-line pulse shaper can simultaneously generate and deliver 1-ps pulses with 31 to 124 GHz repetition-rates over 20 km of single-mode fiber without dispersion-compensating fiber.
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