Ab initio description of magnetic polarons in a Mott insulator

TL;DR

This paper uses advanced Monte Carlo simulations to reveal the detailed real-space structure of magnetic polarons in a Mott insulator, providing insights into their role in strongly correlated electronic systems.

Contribution

It presents the first unbiased, high-precision real-space data of magnetic polarons in the $t$-$J$ model at low temperatures, overcoming the sign problem limitations.

Findings

Revealed the internal structure of magnetic polarons in the $t$-$J$ model.

Provided data comparable to quantum gas microscopy but at lower temperatures.

Enhanced understanding of polarons' influence on transport in Mott insulators.

Abstract

Polarons are among the most elementary quasiparticles of interacting quantum matter, consisting of a charge carrier dressed by an excited background. In Mott insulators, they take the form of a dopant surrounded by a distorted spin-background and are expected to dictate effective mass, transport properties and interactions between carriers. Despite the fundamental importance of polarons for the electronic structure of strongly correlated systems, access to their internal structure was only recently realized in experiments, while theoretical results are still lacking due to the sign problem. Here we report unbiased high-precision data obtained from worm-algorithm Monte Carlo that reveal the real-space structure of a polaron in the $t$-$J$ model deep inside the region where the sign problem becomes significant. These results are directly comparable to recent quantum gas microscopy experiments, but give access to significantly lower temperatures.