Critical number of atoms for attractive Bose-Einstein condensates with cylindrically symmetrical traps
Abstract
We calculated, within the Gross-Pitaevskii formalism, the critical number of atoms for Bose-Einstein condensates with two-body attractive interactions in cylindrical traps with different frequency ratios. In particular, by using the trap geometries considered by the JILA group [Phys. Rev. Lett. 86, 4211 (2001)], we show that the theoretical maximum critical numbers are given approximately by Nc = 0.55 (l0/|a|). Our results also show that, by exchanging the frequencies ωz and ω, the geometry with ω < ωz favors the condensation of larger number of particles. We also simulate the time evolution of the condensate when changing the ground state from a=0 to a<0 using a 200ms ramp. A conjecture on higher order nonlinear effects is also added in our analysis with an experimental proposal to determine its signal and strength.
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