Abstract
We study the properties of spin-less non-interacting fermions trapped in a confining potential in one dimension but in the presence of one or more impurities which are modelled by delta function potentials. We use a method based on the single particle Green's function. For a single impurity placed in the bulk, we compute the density of the Fermi gas near the impurity. Our results, in addition to recovering the Friedel oscillations at large distance from the impurity, allow the exact computation of the density at short distances. We also show how the density of the Fermi gas is modified when the impurity is placed near the edge of the trap in the region where the unperturbed system is described by the Airy gas. Our method also allows us to compute the effective potential felt by the impurity both in the bulk and at the edge. In the bulk this effective potential is shown to be a universal function only of the local Fermi wave vector, or equivalently of the local fermion density. When the impurity is placed near the edge of the Fermi gas, the effective potential can be expressed in terms of Airy functions. For an attractive impurity placed far outside the support of the fermion density, we show that an interesting transition occurs where a single fermion is pulled out of the Fermi sea and forms a bound state with the impurity. This is a quantum analogue of the well-known Baik-Ben Arous-Péché (BBP) transition, known in the theory of spiked random matrices. The density at the location of the impurity plays the role of an order parameter. We also consider the case of two impurities in the bulk and compute exactly the effective force between them mediated by the background Fermi gas.
Highlights
Noninteracting fermions in a confining trap is a topic of much current interest, especially in the context of cold atom where important experimental advances have been made over the last few decades [1,2,3,4,5]
In all the three cases, we compute the effective potential felt by the impurity due to the background Fermi gas
In case (iii), for an attractive impurity, we show that an interesting transition occurs where a single fermion is pulled out of the Fermi sea and forms a bound state with the impurity
Summary
Noninteracting fermions in a confining trap is a topic of much current interest, especially in the context of cold atom where important experimental advances have been made over the last few decades [1,2,3,4,5]. The problem of an impurity in a non-homogeneous free Fermi gas confined in a harmonic potential, or equivalently the Tonks-Girardeau gas in the strongly repulsive limit, has been extensively studied [24,25,26,27] These studies are based on an analytic derivation for the wave functions due to the impurity and a a numerical summation to compute the local density and the energy change due to the impurity. In case (iii), for an attractive impurity, we show that an interesting transition occurs where a single fermion is pulled out of the Fermi sea and forms a bound state with the impurity This is a quantum analogue of the classical BaikBen Arous-Péché (BBP) transition [28, 29], known in the theory of spiked random matrices, where an eigenvalue detaches from the bounded support of the eigenvalues, due to a rankone perturbation. The set up of immobile impurities that we study in this paper is more difficult to access experimentally, it has been suggested that impurities could be introduced by superimposing an optical lattice on an overall trapping potential [38]
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