Enhancement and sign change of magnetic correlations in a driven quantum many-body system

TL;DR

This study demonstrates how periodic driving in a quantum simulation can manipulate magnetic correlations, enabling control over their strength and sign, and offers insights into Floquet engineering for strongly correlated systems.

Contribution

The paper provides experimental evidence of controlling magnetic correlations via Floquet engineering in a driven quantum many-body system, including correlation enhancement and sign reversal.

Findings

Anti-ferromagnetic correlations can be reduced, enhanced, or switched to ferromagnetic.

High-frequency regime validates effective Floquet-Hamiltonian description.

Near-resonant driving allows independent control of tunnelling and magnetic exchange energies.

Abstract

Periodic driving can be used to coherently control the properties of a many-body state and to realize new phases which are not accessible in static systems. For example, exposing materials to intense laser pulses enables to provoke metal-insulator transitions, control the magnetic order and induce transient superconducting behaviour well above the static transition temperature. However, pinning down the responsible mechanisms is often difficult, since the response to irradiation is governed by complex many-body dynamics. In contrast to static systems, where extensive calculations have been performed to explain phenomena such as high-temperature superconductivity, theoretical analyses of driven many-body Hamiltonians are more demanding and new theoretical approaches have been inspired by the recent observations. Here, we perform an experimental quantum simulation in a periodically modulated hexagonal lattice and show that anti-ferromagnetic correlations in a fermionic many-body system can be reduced or enhanced or even switched to ferromagnetic correlations. We first demonstrate that in the high frequency regime, the description of the many-body system by an effective Floquet-Hamiltonian with a renormalized tunnelling energy remains valid, by comparing the results to measurements in an equivalent static lattice. For near-resonant driving, the enhancement and sign reversal of correlations is explained by a microscopic model, in which the particle tunnelling and magnetic exchange energies can be controlled independently. In combination with the observed sufficiently long lifetime of correlations, Floquet engineering thus constitutes an alternative route to experimentally investigate unconventional pairing in strongly correlated systems.