Title :
Electromagnetic Modeling of Third-Order Nonlinearities in Photonic Crystal Fibers Using a Vector Two-Dimensional FDTD Algorithm
Author :
Salski, B. ; Karpisz, T. ; Buczynski, R.
Author_Institution :
Inst. of Radioelectron., Warsaw Univ. of Technol., Warsaw, Poland
Abstract :
An algorithm accounting for dispersive and third-order nonlinear effects in a vector two-dimensional FDTD method is developed and validated in this paper. Kerr and Raman phenomena are implemented in FDTD using a new approach, which combines the accuracy of a rigorous FDTD update scheme and the speed of an approximate solution. As it is shown in this paper, the proposed method is applicable to the mode analysis of waveguide structures, like photonic crystal fibers, where the appropriate balance between dispersion and nonlinear phenomena is essential for supercontinuum generation. Several computational examples discussed in this paper successfully validate the proposed method.
Keywords :
Raman spectra; finite difference time-domain analysis; holey fibres; nonlinear optical susceptibility; optical Kerr effect; optical fibre dispersion; photonic crystals; supercontinuum generation; Kerr phenomena; Raman phenomena; dispersive nonlinear effects; electromagnetic modeling; finite difference time-domain analysis; mode analysis; photonic crystal fibers; supercontinuum generation; third-order nonlinearities; vector two-dimensional FDTD algorithm; waveguide structures; Dispersion; Finite difference methods; Glass; Mathematical model; Nonlinear optics; Refractive index; Time-domain analysis; FDTD; Kerr; Raman; photonic crystal fiber; supercontinuum;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2015.2421522
