# Itinerancy-dependent non-collinear spin textures in SrFeO3, CaFeO3, and   CaFeO3/SrFeO3 heterostructures probed via resonant x-ray scattering

**Authors:** Paul C. Rogge, Robert J. Green, Ronny Sutarto, Steven J. May

arXiv: 1906.09998 · 2019-08-14

## TL;DR

This study investigates how electron itinerancy influences the formation of complex multi-q spin textures in epitaxial films of SrFeO3 and CaFeO3, revealing metallicity's key role in stabilizing multi-q states.

## Contribution

It demonstrates the impact of electron itinerancy on non-collinear spin textures, contrasting metallic SrFeO3 with insulating CaFeO3, and explores their behavior in heterostructures using resonant x-ray scattering.

## Key findings

- SrFeO3 exhibits multi-q spin structures with asymmetric magnetic Bragg peaks.
- CaFeO3 shows simple single-q helical order with symmetric peaks.
- Electron itinerancy is crucial for stabilizing multi-q spin textures.

## Abstract

Non-collinear, multi-q spin textures can give rise to exotic, topologically protected spin structures such as skyrmions, but the reason for their formation over simple single-q structures is not well understood. While lattice frustration and the Dzyaloshinskii-Moriya interaction are known to produce non-collinear spin textures, the role of electron itinerancy in multi-q formation is much less studied. Here we investigated the non-collinear, helical spin structures in epitaxial films of the perovskite oxides SrFeO3 and CaFeO3 using magnetotransport and resonant soft x-ray magnetic diffraction. Metallic SrFeO3 exhibits features in its magnetoresistance that are consistent with its recently proposed multi-q structure. Additionally, the magnetic Bragg peak of SrFeO3 measured at the Fe L edge resonance energy asymmetrically broadens with decreasing temperature in its multi-q state. In contrast, insulating CaFeO3 has a symmetric scattering peak with an intensity 10x weaker than SrFeO3. Enhanced magnetic scattering at O K edge prepeak energies demonstrates the role of a negative charge transfer energy and the resulting oxygen ligand holes in the magnetic ordering of these ferrates. By measuring magnetic diffraction of CaFeO3/SrFeO3 superlattices with thick CaFeO3 layers, we find that the CaFeO3 helical ordering is coherent across 1 unit cell-thick SrFeO3 layers but not 6 unit cell-thick layers. We conclude that insulating CaFeO3 supports only a simple single-q helical structure in contrast to metallic SrFeO3 that hosts multi-q structures. Our results provide important insight into the role of electron itinerancy in the formation of multi-q spin structures.

## Full text

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## Figures

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## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1906.09998/full.md

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Source: https://tomesphere.com/paper/1906.09998