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Two-dimensional discrete solitons in rotating lattices

arXiv:0709.3399 · doi:10.1103/PhysRevE.76.046608

Abstract

We introduce a two-dimensional (2D) discrete nonlinear Schrödinger (DNLS) equation with self-attractive cubic nonlinearity in a rotating reference frame. The model applies to a Bose-Einstein condensate stirred by a rotating strong optical lattice, or light propagation in a twisted bundle of nonlinear fibers. Two species of localized states are constructed: off-axis fundamental solitons (FSs), placed at distance $R$ from the rotation pivot, and on-axis (R=0) vortex solitons (VSs), with vorticities $% S=1$ and 2. At a fixed value of rotation frequency $Ω$, a stability interval for the FSs is found in terms of the lattice coupling constant $C$, $% 0<C<C_{\mathrm{cr}}(R)$, with monotonically decreasing $C_{\mathrm{cr}}(R)$. VSs with S=1 have a stability interval, $\tilde{C}_{\mathrm{cr}%}^{(S=1)}(Ω)<C<C_{\mathrm{cr}}^{(S=1)}(Ω)$, which exists for $% Ω$ below a certain critical value, $Ω_{\mathrm{cr}}^{(S=1)}$. This implies that the VSs with S=1 are \emph{destabilized} in the weak-coupling limit by the rotation. On the contrary, VSs with S=2, that are known to be unstable in the standard DNLS equation, with $Ω=0$, are \emph{stabilized} by the rotation in region $0<C<C_{\mathrm{cr}}^{(S=2)}$%, with $C_{\mathrm{cr}}^{(S=2)}$ growing as a function of $Ω$. Quadrupole and octupole on-axis solitons are considered too, their stability regions being weakly affected by $Ω\neq 0$.

To be published in Physical Review E