Polaron residue and spatial structure in a Fermi gas

Abstract

We study the problem of a mobile impurity of mass M interacting via a s-wave broad or narrow Feshbach resonance with a Fermi sea of particles of mass m. Truncating the Hilbert space to at most one pair of particle-hole excitations of the Fermi sea, we determine ground state properties of the polaronic branch other than its energy, namely the polaron quasiparticle residue Z, and the impurity-to-fermion pair correlation function G(x). We show that G(x) deviates from unity at large distances as -(A\4+B\4 2 k\F x)/(k\F x)4, where k\F is the Fermi momentum; since A\4>0 and B\4>0, the polaron has a diverging rms radius and exhibits Friedel-like oscillations. In the weakly attractive limit, we obtain analytical results, that in particular detect the failure of the Hilbert space truncation for a diverging mass impurity, as expected from Anderson orthogonality catastrophe; at distances between 1/k\F and the asymptotic distance where the 1/x4 law applies, they reveal that G(x) exhibits an intriguing multiscale structure.