Phases and dynamics of few fermionic impurities immersed in two-dimensional boson droplets

TL;DR

This paper investigates the ground state and non-equilibrium dynamics of a few fermionic impurities in a two-dimensional bosonic droplet, revealing a transition from delocalized to localized states and complex excitation patterns due to induced interactions and back-action effects.

Contribution

It introduces a detailed analysis of impurity localization, induced interactions, and back-action effects in fermion-boson droplet mixtures, advancing understanding beyond simplified models.

Findings

Fermions transition from delocalized to localized with increasing attraction.

Induced fermion-fermion interactions grow stronger, affecting impurity behavior.

Complex density patterns emerge during interaction quenches, indicating rich dynamical phenomena.

Abstract

We unravel the ground state properties and emergent non-equilibrium dynamics of a mixture consisting of a few spin-polarized fermions embedded in a two-dimensional bosonic quantum droplet. For an increasingly attractive droplet-fermion interaction we find a transition from a spatially delocalized fermion configuration to a state where the fermions are highly localized and isolated. This process is accompanied by the rise of induced fermion-fermion interactions mediated by the droplet. Additionally, for increasing attractive droplet-fermion coupling, undulations in the droplet density occur in the vicinity of the fermions manifesting the back-action of the latter. Following interaction quenches from strong attractive to weaker droplet-fermion couplings reveals the spontaneous nucleation of complex excitation patterns in the fermion density such as ring and cross shaped structures. These stem from the enhanced interference of the fermions that remain trapped within the droplet, which emulates, to a good degree, an effective potential for the fermions. The non-negligible back-action of the droplet manifests itself in the fact that the effective potential predictions are less accurate at the level of the many-body wave function. Our results provide a paradigm for physics beyond the reduced single-component droplet model, unveiling the role of back-action in droplets and the effect of induced mediated interactions.