Condensed Fraction of an Atomic Bose Gas Induced by Critical Correlations

Abstract

We study the condensed fraction of a harmonically-trapped atomic Bose gas at the critical point predicted by mean-field (MF) theory. The non-zero condensed fraction f0 is induced by critical correlations which increase the transition temperature Tc above cMF. Unlike the Tc shift in a trapped gas, f0 is sensitive only to the critical behaviour in the quasi-uniform part of the cloud near the trap centre. To leading order in the interaction parameter a/λ0, where a is the s-wave scattering length and λ0 the thermal wavelength, we expect a universal scaling f0 (a/λ0)4. We experimentally verify this scaling using a Feshbach resonance to tune a/λ0. Further, using the local density approximation, we compare our measurements with the universal result obtained from Monte-Carlo simulations for a uniform system, and find excellent quantitative agreement.