Molecule Oxygen Induced Ferromagnetism and Half-metallicity in {\alpha}-BaNaO4: A First Principles Study

TL;DR

This study uses first principles calculations to demonstrate that tetragonal {1}BaNaO4 is a stable half-metal with ferromagnetic ordering and a Curie temperature of 120 K, driven by the arrangement of O2 dimers.

Contribution

It reveals that the geometric arrangement of O2 dimers in {1}BaNaO4 induces ferromagnetism and half-metallicity, a novel finding in this class of compounds.

Findings

{1}BaNaO4 is a stable half-metal with a Curie temperature of 120 K.

O2 dimers carry a local magnetic moment of 0.5 {5}B.

Ferromagnetic coupling occurs within and between layers, driven by dimer arrangement.

Abstract

Molecule oxygen resembles 3d and 4f metals in exhibiting long-range spin ordering and electron strong correlated behaviors in compounds. The ferromagnetic spin ordering and half-metallicity, however, are quite elusive and have not been well acknowl-edged. In this article, we address this issue to study how spins will interact each other if the oxygen dimers are arranged in a dif-ferent way from that in the known super- and per-oxides by first principles calculations. Based on the results of structure search, thermodynamic study and lattice dynamics, we show that tetragonal {\alpha}-BaNaO4 is a stable half-metal with a Curie temperature at 120 K, a first example in this class of compounds. Like 3d and 4f metals, the O2 dimer carries a local magnetic moment 0.5 {\mu}B due to the unpaired electrons in its {\pi}* orbitals. This compound can be regarded as forming from the O2 dimer layers stacking in a head to head way. Different from that in AO2 (A=K, Rb, Cs), the spins are both ferromagnetically coupled within and between the layers. Spin polarization occurs in {\pi}* orbitals with spin-up electrons fully occupying the valence band and spin-down electrons partially the conduction band, forming the semiconducting and metallic channels, respectively. Our results highlight the im-portance of geometric arrangement of O2 dimers in inducing ferromagnetism and other novel properties in O2 dimer containing compounds.