Field Induced Orbital Antiferromagnetism in Mott Insulators

TL;DR

This paper introduces a new electromagnetic phenomenon in Mott insulators where orbital electric currents induce antiferromagnetic order, enabling detection of elusive spin currents through various spectroscopic methods.

Contribution

It reveals a novel spin-charge current coupling mechanism in Mott insulators, demonstrated via a Hubbard model on a frustrated ladder, with implications for detecting spin currents.

Findings

Orbital electric currents induce antiferromagnetic order.

Mechanism enables detection of spin currents.

Validated through Hubbard model simulations.

Abstract

We report on a new electromagnetic phenomenon that emerges in Mott insulators, i.e., materials that do not conduct electricity because of strong electronic Coulomb repulsion. The phenomenon manifests as antiferromagnetic ordering due to orbital electric currents which are spontaneously generated from the coupling between spin currents and an external homogenous magnetic field. This novel spin-charge current effect provides the mechanism to detect the so far elusive spin currents by means of unpolarized neutron scattering, nuclear magnetic resonance or muon spectroscopy. We illustrate this mechanism by solving a half-filled Hubbard model on a frustrated ladder, a simple but nontrivial case of strongly interacting electrons.