# Successive spin reorientation and rare earth ordering in   Nd$_{0.5}$Dy$_{0.5}$FeO$_{3}$: Experimental and $Ab$-$initio$ investigations

**Authors:** Ankita Singh, Sarita Rajput, Padmanabhan Balasubramanian, M. Anas,, Francoise Damay, C.M.N. Kumar, Gaku Eguchi, T. Maitra, V.K. Malik

arXiv: 1904.05837 · 2020-10-28

## TL;DR

This study investigates the complex magnetic behavior of Nd$_{0.5}$Dy$_{0.5}$FeO$_{3}$, revealing unusual spin reorientation and rare-earth magnetic ordering through combined experimental and ab initio methods.

## Contribution

It provides new insights into the spin reorientation process and rare-earth ordering in mixed orthoferrites, highlighting the role of exchange interactions and anisotropy.

## Key findings

- Gradual spin reorientation of Fe$^{3+}$ observed between 75-20 K.
- Re-emergence of Fe$^{3+}$ magnetic structure below 10 K.
- Rare-earth ordering involving Nd$^{3+}$/Dy$^{3+}$ confirmed by experiments and calculations.

## Abstract

In present study, the magnetic structure and spin reorientation of mixed doped orthoferrite Nd$_{0.5}$Dy$_{0.5}$FeO$_3$ have been investigated. Similar to both parent compounds (NdFeO$_3$ and DyFeO$_3$), the magnetic structure of Fe$^{3+}$ belongs to ${\Gamma}_{4}$ irreducible representation (G$_{x}$, F$_{z}$) at room temperature. The experimental measurements confirmed the spin reorientation where magnetic structure of Fe$^{3+}$ changes from ${\Gamma}_{4}$ to ${\Gamma}_{2}$(F$_{x}$, G$_{z}$) between 75 and 20 \,K while maintaining G-type configuration. Such a gradual spin reorientation is unusual since the large single ion anisotropy of Dy$^{3+}$ ions causes an abrupt ${\Gamma}_{4}$${\rightarrow}$ ${\Gamma}_{1}$(G$_{y}$) spin reorientation in DyFeO$_3$. Between 20 and 10 \,K, the Fe$^{3+}$ magnetic structure is represented by ${\Gamma}_{2}$ (F$_{x}$, G$_{z}$). Unexpectedly, magnetic structure of Fe$^{3+}$ with ${\Gamma}_{4}$ representation re-emerges below 10\,K which also coincides with the development of rare-earth (Nd$^{3+}$/Dy$^{3+}$) magnetic ordering having C$_{y}$ configuration with magnetic moment of 1.8 ${\mu}_{B}$. The absence of any signature of second order phase transition in the specific heat confirms the role of $R$(Nd$^{3+}$/Dy$^{3+}$)-Fe$^{3+}$ exchange interaction in the observed "rare-earth ordering" unlike DyFeO$_3$ where Dy$^{3+}$ ordering takes place independently to the magnetic ordering of Fe$^{3+}$ magnetic structure. Our (DFT+U+SO) calculations show that the C-type arrangement of rare-earth ions (Nd$^{3+}$/Dy$^{3+}$) with ${\Gamma}_{2}$ configuration for Fe$^{3+}$ moments is the ground state whereas ${\Gamma}_{4}$ phase is energetically very close. Nd-Fe and Nd-Dy exchange interactions, estimated from DFT, are observed to have significant roles in the rare earth ordering and Fe spin reorientation corroborating our experimental results.

## Full text

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## Figures

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## References

46 references — full list in the complete paper: https://tomesphere.com/paper/1904.05837/full.md

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Source: https://tomesphere.com/paper/1904.05837