The origin of ferromagnetic interactions in NaMnCl$_3$: how the response theory reconciles with Goodenough-Kanamori-Anderson rules

TL;DR

This paper investigates the magnetic interactions in NaMnCl₃, revealing that ligand site Stoner coupling significantly influences ferromagnetic contributions, challenging traditional views and aligning with Goodenough-Kanamori-Anderson rules.

Contribution

It introduces a linear response approach to incorporate ligand Stoner coupling effects into exchange interaction calculations, improving understanding of magnetic behavior in NaMnCl₃.

Findings

Ligand Stoner coupling ${\

\}$ significantly affects ferromagnetic interactions.

The nearly filled Cl 3p shell makes ${\

Abstract

The on-site Coulomb repulsion $U$ is the key ingredient for describing the magnetic properties of Mott insulators, leading to a popular believe that many limitations of the density-functional theory based methods can be cured by artificially incorporating such on-site interactions for localized electrons in the model form. The layered antiferromagnet NaMnCl$_3$ reveals quite a different story: while the Coulomb $U$ on the Mn sites controls the strength of antiferromagnetic superexchange interactions, an equally important parameter is the Stoner coupling ${\cal I}_{\rm Cl}$ on the ligand sites. The latter is responsible for large ferromagnetic contributions to the interatomic exchange interactions, which in NaMnCl$_3$ nearly cancel the effect of the superexchange interactions. Although such behavior is anticipated from the phenomenological Goodenough-Kamanori-Anderson rules, the quantitative description of the ligand-related contributions remains disputable. Considering NaMnCl$_3$ as an example, we discuss how they can be generally taken into account in the linear response theory to regain the dependence of the exchange interactions on ${\cal I}_{\rm Cl}$. The problem is complicated by the fact that, for the nearly filled Cl $3p$ shell, the parameters ${\cal I}_{\rm Cl}$ are sensitive to the model assumptions.