Spectral Phase and Intensity Evolutions of Supercontinuum Generation in a Biconical Tapered Fiber

Supercontinuum (SC) spectrum generation in a biconical tapered fiber is theoretically studied by taking into account the varying dispersion characteristics. Our numerical model is based on the extended nonlinear Schrodinger equation including higher-order dispersive terms, self-steepening, and Raman nonlinearity terms. We demonstrate how the group velocity dispersion and effective core area vary in the input taper region, which is significant for the broadening of the SC spectrum in the subsequent waist region. The evolutions of the unwrapped spectral phase and the spectral intensity along the transition and waist regions of the tapered fiber are also investigated in detail. It is found that the output taper has a considerable effect on the nonlinear variation of the spectral phase, e.g., 6.5 rad/THz in the infrared range of 280–300 THz (i.e., 1071–1000 nm in wavelength) and 21 rad/THz in the visible range of 600–620 THz (i.e., 500–484 nm).