# In Quest of a Ferromagnetic Insulator -- Structure Controlled Magnetism   in Mg-Ti-O Thin Films

**Authors:** Johannes Frantti, Yukari Fujioka, Christopher Rouleau, Alexandra, Steffen, Alexander Puretzky, Nickolay Lavrik, Ilia N. Ivanov, Harry M., Meyer

arXiv: 1906.10975 · 2019-09-04

## TL;DR

This study demonstrates that the magnetic and electric properties of Mg-Ti-O thin films can be precisely controlled through cation arrangement, enabling the creation of ferromagnetic insulators with potential applications in spin wave devices.

## Contribution

It reveals that cation rearrangement in Mg-Ti-O films can induce ferromagnetic insulating phases, challenging traditional rules and enabling defect-free multilayer structures.

## Key findings

- Magnetic and electric properties are tunable via cation arrangement.
- Ferromagnetic insulating phases can be achieved with specific cation configurations.
- Cation rearrangement allows for defect-free interfaces in multilayer structures.

## Abstract

Ferromagnetic insulator thin films can convey information by spin waves, avoiding charge displacement and Eddy current losses. The sparsity of high-temperature insulating ferromagnetic materials hinders the development of spin wave based devices. Stoichiometric magnesium titanate, MgTiO$_3$, has an electronic-energy-band structure in which all bands are either full or empty, being a paramagnetic insulator. The MgTiO$_3$ ilmenite consists of ordered octahedra and cation network in which one third of the octahedra are vacant, one third host magnesium and one third titanium. By giving up these characteristics, a rich variety of different magnetic structures can be formed. Our experiments and electronic-energy-band-structure computations show that the magnetic and electric properties of Mg-Ti-O films can drastically be changed and controlled by Mg- and Ti-cation arrangement and abundancy in the octahedra. Insulating titanium- and semiconducting magnesium-rich films were ferromagnetic up to elevated temperatures. The presence and origin of ferromagnetic insulating phase in the films is not apparent - the expectation, based on the well-established rules set by Goodenough and Kanamori, is paramagnetic or antiferromagnetic ordering. We show that ferro- and paramagnetic phases, possessing the same stoichiometry, can be obtained by merely rearranging the cations, thus allowing defect-free interfaces in multilayer structures.

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Source: https://tomesphere.com/paper/1906.10975