Polarization modulation instability (PMI) in birefringent photonic crystal fibers has been observed in the normal dispersion regime with a frequency shift of 64 THz between the generated frequencies and the pump frequency. The generated sidebands are orthogonally polarized to the pump. From the observed PMI frequency shift and the measured dispersion, we determined the phase birefringence to be 5.3 x 10(-5) at a pump wavelength of 647.1 nm. This birefringence was used to estimate the PMI gain as a function of pump wavelength. Four-wave mixing experiments in both the normal and the anomalous dispersion regimes generated PMI frequency shifts that show good agreement with the predicted values over a 70 THz range. These results could lead to amplifiers and oscillators based on PMI.
Large frequency shift parametric sidebands are shown to be sensitive to dispersion fluctuations. Comparing experimentally measured and theoretical calculated sideband conversion efficiencies allows us to estimate the uniformity of the photonic crystal fiber used.Introduction.
Two forms of vector modulation instability are observed in photonic crystal fiber. The strongly varying dispersion of these fibers result in complicated phasematching curves. We experimentally demonstrate the existence of broad regions of parametric gain.
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