Abstract EN:

One of the recent and exciting aspects in the fields of cold atoms is the study of Bose-Fermi mixtures. Several boson-fermion mixtures have been realized and their properties have been theoretically studied using for instance Mean Field approximation or Quantum Monte Carlo (QMC) methods. The latter gives us exact results for one dimensional system. RPA, historically developed for fermions, is tested on a bosonic model, the anharmonic oscillator, to check its pertinence on non trivial bosonic systems. It's applied on the Richardson Model where trapped bosonic atoms can create bound states (diatomic molecules). Then RPA is applied to Bose Fermi mixtures located on a 1D optical lattice. In our work we consider BF pairing in a discrete environment of bosons and fully spin-polarized fermions. The system is modeled by a 1D Bose-Fermi Hubbard Hamiltonian with attractive BF interaction. One of the interests of such a system is to check th validity and limits of T-matrix approach, previously employed int he 3D case, by comparing with QMC results. We discuss the T-matrix approximation applied to a BF mixture for a discrete number of sites and show results obtained for the ground state energy, the excitation energies and occupation numbers. We discuss the continuous case underlining the appearance of a stable weak coupling BF pairing mode. This Cooper-pair-like mode exists at any small value of the interaction due to the presence of a Fermi surface.