Abstract
Two families of Gaussian-type soliton solutions of the (n+1)-dimensional Schrödinger equation with cubic and power-law nonlinearities in -symmetric potentials are analytically derived. As an example, we discuss some dynamical behaviors of two dimensional soliton solutions. Their phase switches, powers and transverse power-flow densities are discussed. Results imply that the powers flow and exchange from the gain toward the loss regions in the cell. Moreover, the linear stability analysis and the direct numerical simulation are carried out, which indicates that spatial Gaussian-type soliton solutions are stable below some thresholds for the imaginary part of -symmetric potentials in the defocusing cubic and focusing power-law nonlinear medium, while they are always unstable for all parameters in other media.
Highlights
The construction of the exact solutions of nonlinear partial differential equations is one of the most important and essential tasks in various branches from mathematical physics, engineering sciences, chemistry to biology [1, 2]
If N~1, Eq (1) is 1DNLSE, and its solutions are 1D spatial soliton solutions
We discuss some dynamical behaviors of two dimensional soliton solutions
Summary
The construction of the exact solutions of nonlinear partial differential equations is one of the most important and essential tasks in various branches from mathematical physics, engineering sciences, chemistry to biology [1, 2]. The nonlinear Schrodinger equation (NLSE) and its relatives play important role in in physics, biology and other fields. The propagation of solitons in parity-time (PT ) symmetric potentials are presently attracting a great interest both from the theoretical and from the applicative point of view [16,17,18,19,20,21,22,23,24,25,26]. The propagation of nonautonomous solitons in optical media with PT symmetry has been a subject of intense investigation [24,25,26]
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