Full counting statistics of interacting lattice gases after an expansion: The role of the condensate depletion in the many-body coherence
Abstract
We study the full counting statistics (FCS) of quantum gases in samples of thousands of interacting bosons, detected atom-by-atom after a long free-fall expansion. In this far-field configuration, the FCS reveals the many-body coherence from which we characterize iconic states of interacting lattice bosons, by deducing the normalized correlations g(n)(0) up to the order n=6. In Mott insulators, we find a thermal FCS characterized by perfectly-contrasted correlations g(n)(0)= n!. In interacting Bose superfluids, we observe small deviations to the Poisson FCS and to the ideal values g(n)(0)=1 expected for a pure condensate. To describe these deviations, we introduce a heuristic model that includes an incoherent contribution attributed to the depletion of the condensate. The predictions of the model agree quantitatively with our measurements over a large range of interaction strengths, that includes the regime where the condensate is strongly depleted by interactions. These results suggest that the condensate component exhibits a full coherence g(n)(0) =1 at any order n up to n=6 and at arbitrary interaction strengths. The approach demonstrated here is readily extendable to characterize a large variety of interacting quantum states and phase transitions.
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