Analytic Methods to Find Beating Transitions of Asymmetric Gaussian Beams in GNLS equations

TL;DR

This paper develops an analytic model to identify and explain transitions in beating behavior of asymmetric Gaussian beams in nonlinear waveguides, matching numerical results and predicting new phenomena.

Contribution

It introduces a simplified Hamiltonian-based analytic approach to locate and analyze beating transitions in asymmetric Gaussian beams within GNLSE models.

Findings

Analytic model accurately predicts beating transition locations.

Identifies a band of energies with a single transition in CQ case.

Explains sudden transition changes with parameter variations in SAT case.

Abstract

In a simple model of propagation of asymmetric Gaussian beams in nonlinear waveguides, described by a reduction to ordinary differential eqautions of generalized nonlinear Schrodinger equations (GNLSEs) with cubic-quintic (CQ) and saturable (SAT) nonlinearities and a graded-index profile, the beam widths exhibit two different types of beating behavior, with transitions between them. We present an analytic model to explain these phenomena, which originate in a 1:1 resonance in a 2 degree-of-freedom Hamiltonian system. We show how small oscillations near a fixed point close to 1:1 resonance in such a system can be approximated using an integrable Hamiltonian and, ultimately, by a single first order differential equation. In particular, the beating transitions can be located from coincidences of roots of a pair of quadratic equations, with coefficients determined (in a highly complex manner) by the internal parameters and initial conditions of the original system. The results of the analytic model agree with numerics of the original system over large parameter ranges, and allow new predictions that can be verified directly. In the CQ case we identify a band of beam energies for which there is only a single beating transition (as opposed to 0 or 2) as the eccentricity is increased. In the SAT case we explain the sudden (dis)appearance of beating transitions for certain values of the other parameters as the grade-index is changed.