Semiclassical solitons in strongly correlated systems of ultracold bosonic atoms in optical lattices

We investigate theoretically soliton excitations and dynamics of their formation in strongly correlated systems of ultracold bosonic atoms in two and three dimensional optical lattices. We derive equations of nonlinear hydrodynamics in the regime of strong interactions and incommensurate fillings, when atoms can be treated as hard core bosons. When parameters change in one direction only we obtain Korteweg–de Vries type equation away from half-filling and modified KdV equation at half-filling. We apply this general analysis to a problem of the decay of the density step. We consider stability of one dimensional solutions to transverse fluctuations. Our results are also relevant for understanding nonequilibrium dynamics of lattice spin models.

► Dynamics of their formation in strongly correlated systems of ultracold bosonic atoms in optical lattices. ► Regime of very strong interactions between atoms, the so-called hard core bosons regime. ► Character of soliton excitations is dramatically different from the usual Gross–Pitaevskii regime.