Quasiparticle properties of long-range impurities in a Bose condensate

Abstract

An impurity immersed in a Bose condensate can form a quasiparticle known as a Bose polaron. When the impurity-boson interaction is short-ranged, the quasiparticle properties can be characterized in terms of the impurity-boson scattering length aIB and the condensate coherence length , a universal description that remains valid irrespective of the bath density n0. Long-ranged interactions -- such as provided by Rydberg or ionic impurities -- introduce an effective interaction range reff as the third length scale. These competing length scales raise the question of whether a universal description remains valid across different bath densities. In this study, we discuss the quasiparticle nature of long-range impurities and its dependence on the length scales n0-1/3, reff, and . We employ two complementary theories -- the coherent state Ansatz and the perturbative Gross-Pitaevskii theory -- which incorporate beyond-Fr\"ohlich interactions. We derive an analytical expression for the beyond-Fr\"ohlich effective mass for a contact interaction and numerically compute the effective mass for long-range impurities. We argue that the coupling parameter |aIB|n01/3 remains the principal parameter governing the properties of the polaron. For weak (|aIB|n01/3 1) and intermediate (|aIB|n01/3 1) values of the coupling parameter, long-range impurities in a Bose condensate are well-described as quasiparticles with a finite quasiparticle weight and a well-defined effective mass. However, the quasiparticle weight becomes significantly suppressed as the effective impurity volume is occupied by an increasing number of bath particles (reffn01/3 1).