# Lattice Disorder Effect on Magnetic Ordering of Iron Arsenides

**Authors:** Athena S. Sefat, Xiaoping P. Wang, Yaohua Liu, Qiang Zou, Mingming Fu,, Zheng Gai, Ganesh Kalaiselvan, Yogesh Vohra, Li Li, David S. Parker

arXiv: 1903.02545 · 2020-02-13

## TL;DR

This paper reveals that local lattice disorder in iron arsenides can enhance magnetic ordering temperatures, challenging the assumption that order correlates directly with higher TN, and explores the structural and magnetic interactions involved.

## Contribution

It demonstrates that local lattice disorder can increase the Neel temperature in iron arsenide crystals, providing new insights into magnetic ordering mechanisms.

## Key findings

- Disordered crystals exhibit higher TN than ordered ones with same composition.
- Shorter Fe-Fe bonds correlate with higher TN in disordered samples.
- Lattice strain influences interlayer magnetic coupling more than planar strain.

## Abstract

This study investigates the changes of magnetic ordering temperature via nano- and mesoscale structural features in an iron arsenide. Although magnetic ground states in quantum materials can be theoretically predicted from known crystal structures and chemical compositions, the ordering temperature is harder to pinpoint due to such local lattice variations. In this work we find surprisingly that a locally disordered material can exhibit a significantly larger Neel temperature (TN) than an ordered material of precisely the same chemical stoichiometry. Here, a EuFe2As2 crystal, which is a 122 parent of iron arsenide superconductors, is found through synthesis to have ordering below TN = 195 K (for the disordered crystal) or TN = 175 K (for the ordered crystal). In the higher TN crystals, there are shorter planar Fe-Fe bonds [2.7692(2) A vs. 2.7745(3) A], a randomized in-plane defect structure, and diffuse scattering along the [00L] crystallographic direction that manifests as a rather broad specific heat peak. For the lower TN crystals, the a-lattice parameter is larger and the in-plane microscopic structure shows defect ordering along the antiphase boundaries, giving a larger TN and a higher superconducting temperature (Tc) upon the application of pressure. First principles calculations find a strong interaction between c-axis strain and interlayer magnetic coupling, but little impact of planar strain on the magnetic order. Neutron single-crystal diffraction shows that the low-temperature magnetic phase transition due to localized Eu moments is not lattice or disorder sensitive, unlike the higher-temperature Fe sublattice ordering. This study demonstrates a higher magnetic ordering point arising from local disorder in 122.

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Source: https://tomesphere.com/paper/1903.02545