Coupled complex Ginzburg-Landau systems with saturable nonlinearity and asymmetric cross-phase modulation

TL;DR

This paper investigates the dynamics of coupled complex Ginzburg-Landau systems with saturable nonlinearity and asymmetric cross-phase modulation, deriving conditions for bounded solutions, amplitude death, and modulational instability, supported by numerical simulations.

Contribution

It introduces a comprehensive analysis of saturable complex Ginzburg-Landau systems with asymmetric XPM, including exact solutions and stability conditions, extending prior models with new analytical and numerical insights.

Findings

Derived conditions for bounded dynamics and amplitude death.

Constructed exact plane wave solutions and analyzed their stability.

Observed spatiotemporal chaos and pattern formation in simulations.

Abstract

We formulate and study dynamics from a complex Ginzburg-Landau system with saturable nonlinearity, including asymmetric cross-phase modulation (XPM) parameters. Such equations can model phenomena described by complex Ginzburg-Landau systems under the added assumption of saturable media. When the saturation parameter is set to zero, we recover a general complex cubic Ginzburg-Landau system with XPM. We first derive conditions for the existence of bounded dynamics, approximating the absorbing set for solutions. We use this to then determine conditions for amplitude death of a single wavefunction. We also construct exact plane wave solutions, and determine conditions for their modulational instability. In a degenerate limit where dispersion and nonlinearity balance, we reduce our system to a saturable nonlinear Schr\"odinger system with XPM parameters, and we demonstrate the existence and behavior of spatially heterogeneous stationary solutions in this limit. Using numerical simulations we verify the aforementioned analytical results, while also demonstrating other interesting emergent features of the dynamics, such as spatiotemporal chaos in the presence of modulational instability. In other regimes, coherent patterns including uniform states or banded structures arise, corresponding to certain stable stationary states. For sufficiently large yet equal XPM parameters, we observe a segregation of wavefunctions into different regions of the spatial domain, while when XPM parameters are large and take different values, one wavefunction may decay to zero in finite time over the spatial domain (in agreement with the amplitude death predicted analytically). While saturation will often regularize the dynamics, such transient dynamics can still be observed - and in some cases even prolonged - as the saturability of the media is increased, as the saturation may act to slow the timescale.