Physical Review X (Apr 2021)

Coupling a Mobile Hole to an Antiferromagnetic Spin Background: Transient Dynamics of a Magnetic Polaron

  • Geoffrey Ji,
  • Muqing Xu,
  • Lev Haldar Kendrick,
  • Christie S. Chiu,
  • Justus C. Brüggenjürgen,
  • Daniel Greif,
  • Annabelle Bohrdt,
  • Fabian Grusdt,
  • Eugene Demler,
  • Martin Lebrat,
  • Markus Greiner

DOI
https://doi.org/10.1103/PhysRevX.11.021022
Journal volume & issue
Vol. 11, no. 2
p. 021022

Abstract

Read online Read online

Understanding the interplay between charge and spin and its effects on transport is a ubiquitous challenge in quantum many-body systems. In the Fermi-Hubbard model, this interplay is thought to give rise to magnetic polarons, whose dynamics may explain emergent properties of quantum materials such as high-temperature superconductivity. In this work, we use a cold-atom quantum simulator to directly observe the formation dynamics and subsequent spreading of individual magnetic polarons. Measuring the density- and spin-resolved evolution of a single hole in a 2D Hubbard insulator with short-range antiferromagnetic correlations reveals fast initial delocalization and a dressing of the spin background, indicating polaron formation. At long times, we find that dynamics are slowed down by the spin exchange time, and they are compatible with a polaronic model with strong density and spin coupling. Our work enables the study of out-of-equilibrium emergent phenomena in the Fermi-Hubbard model, one dopant at a time.