Dipolar bright solitons and solitary vortices in a radial lattice

Abstract

Stabilizing vortex solitons with high values of the topological charge, S, is a challenging issue in optics, studies of Bose-Einstein condensates (BECs) and other fields. To develop a new approach to the solution of this problem, we consider a two-dimensional dipolar BEC under the action of an axisymmetric radially periodic lattice potential, V(r) (2r+δ ), with dipole moments polarized perpendicular to the system's plane, which gives rise to isotropic repulsive dipole-dipole interactions (DDIs). Two radial lattices are considered, with δ =0 and π , i.e., a potential maximum or minimum at r=0, respectively. Families of vortex gapsoliton (GSs) with S=1 and S≥ 2, the latter ones often being unstable in other settings, are completely stable in the present system (at least, up to S=11), being trapped in different annular troughs of the radial potential. The vortex solitons with different S may stably coexist in sufficiently far separated troughs. Fundamental GSs, with S=0, are found too. In the case of δ =0, the fundamental solitons are ring-shaped modes, with a local minimum at r=0.At δ =π , they place a density peak at the center.