Abstract
We investigate the Fermi polaron problem in a spin-1/2 Fermi gas in an optical lattice for the limit of both strong repulsive contact interactions and one dimension. In this limit, a polaronic-like behaviour is not expected, and the physics is that of a magnon or impurity. While the charge degrees of freedom of the system are frozen, the resulting tight-binding Hamiltonian for the impurity’s spin exhibits an intriguing structure that strongly depends on the filling factor of the lattice potential. This filling dependency also transfers to the nature of the interactions for the case of two magnons and the important spin balanced case. At low filling, and up until near unit filling, the single impurity Hamiltonian faithfully reproduces a single-band, quasi-homogeneous tight-binding problem. As the filling is increased and the second band of the single particle spectrum of the periodic potential is progressively filled, the impurity Hamiltonian, at low energies, describes a single particle trapped in a multi-well potential. Interestingly, once the first two bands are fully filled, the impurity Hamiltonian is a near-perfect realisation of the Su–Schrieffer–Heeger model. Our studies, which go well beyond the single-band approximation, that is, the Hubbard model, pave the way for the realisation of interacting one-dimensional models of condensed matter physics.
Highlights
Strongly-interacting trapped onedimensional multicomponent systems, which suffer from huge ground state degeneracies, have been shown to be tractable by means of freezing the charge degrees of freedom and the reduction of the spin sector to an effective spin chain model [1,2,3]
Ultracold atom experimental techniques have been developed to reach the few-body limit in one-dimensional set-ups [22, 23]
Inspired by the capability of cold atom experiments, we consider the realisable scenario of a single spin impurity in a one-dimensional strongly repulsive Fermi gas in an optical lattice potential
Summary
Strongly-interacting trapped onedimensional multicomponent systems, which suffer from huge ground state degeneracies, have been shown to be tractable by means of freezing the charge degrees of freedom and the reduction of the spin sector to an effective spin chain model [1,2,3] With this development, there has been considerable theoretical work on strongly interacting one-dimensional systems in recent years [4,5,6,7,8,9,10,11,12,13,14,15,16], including for the case of a single spin impurity [17,18,19]. Inspired by the capability of cold atom experiments, we consider the realisable scenario of a single spin impurity in a one-dimensional strongly repulsive Fermi gas in an optical lattice potential This is the strongly repulsive one-dimensional limit of the Fermi polaron problem and goes beyond the single-band approximation of the Hubbard model. V, we extend the discussion to multiple magnons, with an emphasis on the nature of the interactions between them
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