³Ô¹ÏÍøÕ¾

Research explores how the magnetic moments of atoms in materials are arranged and interact

ANSTO

In this , researchers from a large international team including ANSTO, investigated the magnetic properties of two unique 2D triangular lattice antiferromagnetic materials (2D-TLHAF)* using various neutron scattering techniques.

Multiferroic materials are being explored for use in advanced computers. Their quantum properties make them suitable for future computing applications, as they can manage and process the significantly larger volume of information more efficiently. Additionally, the unique properties of 2D magnets, such as flexibility and stackability, an ability to control layers of quantum devices or materials to create more efficient systems, have application in magnetism and spintronics.

Triangular Lattice
(a) Triangular lattice formed by Mn atoms, with intraplanar exchange interactions (𝐽1 and 𝐽2) and interplanar exchange interactions (𝐽𝑐1 and 𝐽𝑐2). The triangular lattice can be a perfect triangular when 𝑥Mn=1/3, where 𝐽1=𝐽2 and 𝐽𝑐1=𝐽𝑐2. (b) Six irreducible representations under 𝑃⁢63⁢𝑐⁢𝑚 symmetry, where Γ1 to Γ4 are irreducible one-dimensional representations, while Γ5 and Γ6 are irreducible two-dimensional representations. (c) The interactions between planes using examples of Γ5⁡(𝑃⁢63) and Γ6⁡(𝑃⁢6′3). Phys. Rev. B 110, 134444 – Published 31 October 2024

The materials, hexagonal h-Lu0.3Y0.7MnO3 and h-Lu0.47Sc0.53FeO3, are a type of frustrated antiferromagnet, which means that the spins of the atoms in the material cannot all align in a way that minimises their energy due to the triangular arrangement of the lattice.

Lead author, instrument scientist Dr Shinichiro Yano said the materials exhibit fascinating and complex magnetic behaviours which has been difficult to investigate by conventional neutron scattering techniques.

Their unique magnetic properties and nontrivial quantum effects that can be observed and measured from the with a setup of polarized neutrons and other neutron instruments at the

The study, published in the American Physical Society Journal, reports two irreducible representations* to describe their magnetic structure.

“These mathematical concepts help us understand how the magnetic moments (spins) of the atoms in these materials are arranged and how they interact with each other.”

Dr Andrew Manning, Helium-3 Polarisation instrument scientist said, “Polarized neutron scattering has shown that accurately describing the magnetic structures of a 2D-TLHAF requires the use of two irreducible representations, rather than relying on the assumption that the system undergoes spin reorientation when using only one irreducible representation.”

Instrument scientist Dr Chin-Wei Wang said, “If we use two irreducible representations to describe these magnetic structures, the spin reorientations reported in these compounds are not as drastic as previously claimed.”

The study also investigated the spin-wave dispersion of both materials based on these magnetic structures. A spin wave is a propagating disturbance in the ordering of a magnetic material.

The study also provides evidence of interplanar interactions in one material, h-Lu0.3Y0.7MnO3, which are absent in the other, h-Lu0.47Sc0.53FeO3.

“Interplanar interactions were thought to be the key to understanding spin reorientations. However, as shown in the paper, interplanar interactions were absent for one of the materials we studied,” said Dr Yano.

These findings also offered fresh insights into the magnetism of spin reorientations and the source of the multiferroicity of this 2D-TLHAF system.

“Even though the two materials are similar in terms of crystal and magnetic structures, the source of multiferroicity and the origin of spin reorientation could be different,” said Dr Yano.

Collaborating organisations included (Taiwan), (US), (CROSS) (Japan), and (KEK) (Japan).

*Γ1 (P63cm) and Γ2 (P63c’m’) for h-Lu0.47Sc0.53FeO3, Γ3 (P6′3cm’) and Γ4 (P6′3c’m) for h-Lu0.3Y0.7MnO3

DOI:

/Public Release. View in full .