# High entropy oxides: An emerging prospect for magnetic rare earth -   transition metal perovskites

**Authors:** Ralf Witte, Abhishek Sarkar, Robert Kruk, Benedikt Eggert, Richard A., Brand, Heiko Wende, Horst Hahn

arXiv: 1901.02395 · 2019-03-27

## TL;DR

This paper explores the magnetic properties of high entropy rare earth-transition metal perovskites, revealing predominant antiferromagnetism and potential for discovering novel magnetic phenomena in these complex, disordered materials.

## Contribution

It provides the first investigation of magnetic behavior in high entropy rare earth-transition metal perovskites, combining experimental magnetometry and spectroscopy to understand their magnetic interactions.

## Key findings

- Predominant antiferromagnetic behavior observed
- Small ferromagnetic contributions possibly from clusters
- Potential for discovering new magnetic phenomena

## Abstract

It has been shown that oxide ceramics containing multiple transition and/or rare-earth elements in equimolar ratios have a strong tendency to crystallize in simple single phase structures, stabilized by the high configurational entropy. In analogy to the metallic alloy systems, these oxides are denoted high entropy oxides (HEOs). The HEO concept allows to access hitherto uncharted areas in the multi-element phase diagram. Among the already realized structures there is the highly complex class of rare earth - transition element perovskites. This fascinating class of materials generated by applying the innovative concept of high entropy stabilization provides a new and manyfold research space with promise of discoveries of unprecedented properties and phenomena. The present study provides a first investigation of the magnetic properties of selected compounds of this novel class of materials. Comprehensive studies by DC and AC magnetometry are combined with element specific spectroscopy in order to understand the interplay between magnetic exchange and the high degree of chemical disorder in the systems. We observe a predominant antiferromagnetic behavior in the single phase materials, combined with a small ferromagnetic contribution possibly stemming from small ferromagnetic clusters or configurations in the antiferromagnetic matrix. In the long term perspective it is proposed to screen the properties of this family of compounds with high throughput methods, including combined experimental and theoretical approaches.

## Full text

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## Figures

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## References

53 references — full list in the complete paper: https://tomesphere.com/paper/1901.02395/full.md

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Source: https://tomesphere.com/paper/1901.02395