Nonlinear waves in a cylindrical Bose-Einstein condensate

We present a calculation of solitary waves propagating in a steady state with constant velocity $v$ along a cigar-shaped Bose-Einstein trap approximated as an infinitely elongated cylinder. For sufficiently weak couplings (densities), the main features of the calculated solitons could be captured by effective one-dimensional (1D) models. However, for stronger couplings of practical interest, the relevant solitary waves are found to be hybrids of quasi-1D solitons and 3D vortex rings. An interesting hierarchy of vortex rings occurs as the effective coupling constant is increased through a sequence of critical values. The energy-momentum dispersion of the above structures is shown to exhibit characteristics similar to a mode proposed sometime ago by Lieb within a strictly 1D model, as well as some rotonlike features.