Abstract
One-particle reduced density matrix functional theory would potentially be the ideal approach for describing Bose-Einstein condensates. It namely replaces the macroscopically complex wavefunction by the simple one-particle reduced density matrix, therefore provides direct access to the degree of condensation and still recovers quantum correlations in an exact manner. We eventually initiate and establish this novel theory by deriving the respective universal functional $\mathcal{F}$ for general homogeneous Bose-Einstein condensates with arbitrary pair interaction. Most importantly, the successful derivation necessitates a particle-number conserving modification of Bogoliubov theory and a solution of the common phase dilemma of functional theories. We then illustrate this novel approach in several bosonic systems such as homogeneous Bose gases and the Bose-Hubbard model. Remarkably, the general form of $\mathcal{F}$ reveals the existence of a universal Bose-Einstein condensation force which provides an alternative and more fundamental explanation for quantum depletion.
Highlights
Bose-Einstein condensation (BEC) is one of the most fascinating quantum phenomena
The general need to describe bosonic quantum systems within and beyond the ordinary BEC regime has urged us very recently to put forward a physical theory for describing interacting bosonic quantum systems [10]
III, we present a particle-number conserving modification of Bogoliubov’s theory which eventually allows us to derive the universal functional within the BEC regime
Summary
Bose-Einstein condensation (BEC) is one of the most fascinating quantum phenomena. While its theoretical prediction by Einstein [1] based on Bose’s work [2] dates back to 1925, the realization of BEC for ultracold atoms in 1995 [3,4,5] has led to a renewed interest. The general need to describe bosonic quantum systems within and beyond the ordinary BEC regime has urged us very recently to put forward a physical theory for describing interacting bosonic quantum systems [10] This bosonic reduced density matrix functional theory (RDMFT) is based on a generalization of the HohenbergKohn theorem, abandons the complex N-boson wave function but still recovers quantum correlations in an exact way. While bosonic RDMFT would potentially be the ideal theory for describing BECs (including the regime of fractional BEC as well as quasicondensation [12]), RDMFT does not trivialize the ground-state problem Instead, it is the fundamental challenge in RDMFT to construct reliable approximations of the universal interaction functional F (γ ) and determine its leading-order behavior in certain physical regimes or its exact form for simplified model systems. In the summary and conclusion, we provide a general idea for constructing higher order functional approximations based on a perturbational theoretical generalization of Bogoliubov theory
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