Author_Institution :
Sch. of Technol., Open Univ. of Israel, Tel Aviv, Israel
Abstract :
This study utilized the laser simulation code Lyra®, which is essentially an upgrade version of the BPM part of the code LAS-CAD®, in order to calculate the transversal modes of a loaded holey fiber. Lyra calculates the 3D distribution of the signal, as well as the super-Gaussian pump distribution in the fiber, using the FFT-BPM method with a non-paraxial split operator. It also calculates the eigenmodes and the corresponding eigenfunctions of the structure, by sampling the field distribution during the propagation, making a least squares analysis to the corresponding power spectrum. The gain model in Lyra is based on a simple two-level approximation to the rate equations with somewhat artificial pump cross-section to allow efficient absorption of the pump radiation (λpump = 0.9 μm, σpump = 0.1 cm-1). The main effect of the gain is to enhance the imaginary refractive index of the core, while somewhat reducing the real index close to the fiber axis. It is found that although higher modes are more easily excited in the unloaded holey fiber, the dominant mode is still very similar in both cases: it has almost the same propagation constant, β = 60766 cm-1, with a characteristic non-circular mode shape. However, the inner part of the mode, where more than 80% of the power resides, is more Gaussian like, with a circular shape for both the loaded and the unloaded fibers. Some more results of nonlinear effects (like Kerr effect) are also presented in the conference.
Keywords :
eigenvalues and eigenfunctions; fibre lasers; laser modes; least squares approximations; optical Kerr effect; optical fibres; optical pumping; photonic crystals; refractive index; 3D signal distribution; FFT-BPM method; Kerr effect; Lyra; artificial pump cross-section; eigenfunctions; eigenmodes; fiber lasers; field distribution sampling; gain effects; gain model; holey fiber modes; imaginary refractive index; laser simulation code; least squares analysis; loaded holey fiber; noncircular mode shape; nonlinear effects; nonparaxial split operator; photonic crystal lasers; power spectrum; propagation constant; pump radiation; rate equations; super-Gaussian pump distribution; transversal modes; two-level approximation; unloaded holey fiber; Eigenvalues and eigenfunctions; Equations; Fiber lasers; Holey fibers; Laser modes; Least squares approximation; Least squares methods; Pump lasers; Sampling methods; Shape;
