Origin of nonlinear contribution to the shift of the critical temperature in atomic Bose-Einstein condensates

Abstract

We discuss a possible origin of the experimentally observed nonlinear contribution to the shift Tc=Tc-Tc0 of the critical temperature Tc in an atomic Bose-Einstein condensate (BEC) with respect to the critical temperature Tc0 of an ideal gas. We found that accounting for a nonlinear (quadratic) Zeeman effect (with applied magnetic field closely matching a Feshbach resonance field B0) in the mean-field approximation results in a rather significant renormalization of the field-free nonlinear contribution b2, namely Tc/Tc0 b2 (a/λ T)2 (where a is the s-wave scattering length, λ T is the thermal wavelength at Tc0) with b2 =γ 2b2 and γ =γ (B0). In particular, we predict b2 42.3 for the B0 403G resonance observed in the \ 39K BEC.