# Nanostructured complex oxides as a route towards thermal behavior in   artificial spin ice systems

**Authors:** Rajesh V. Chopdekar, Binzhi Li, Thomas A. Wynn, Michael S. Lee, Yue, Jia, Zhiqi Liu, Michael D. Biegalski, Scott T. Retterer, Anthony T. Young,, Andreas Scholl, Yayoi Takamura

arXiv: 1705.02309 · 2017-07-07

## TL;DR

This study demonstrates how thermal annealing near the Curie temperature influences the magnetic configurations of nano-islands in artificial spin ice, enabling controlled exploration of their energy landscape.

## Contribution

It introduces a method to thermally manipulate artificial spin ice configurations using nanostructured complex oxides near their Curie temperature.

## Key findings

- Lower energy configurations are more likely when annealed just below T_C.
- Thermal activation at 325 K allows nano-islands to explore their energy landscape.
- Ensembles transition to lower energy states over time at this temperature.

## Abstract

We have used soft x-ray photoemission electron microscopy to image the magnetization of single domain La$_{0.7}$Sr$_{0.3}$MnO$_{3}$ nano-islands arranged in geometrically frustrated configurations such as square ice and kagome ice geometries. Upon thermal randomization, ensembles of nano-islands with strong inter-island magnetic coupling relax towards low-energy configurations. Statistical analysis shows that the likelihood of ensembles falling into low-energy configurations depends strongly on the annealing temperature. Annealing to just below the Curie temperature of the ferromagnetic film (T$_{C}$ = 338 K) allows for a much greater probability of achieving low energy configurations as compared to annealing above the Curie temperature. At this thermally active temperature of 325 K, the ensemble of ferromagnetic nano-islands explore their energy landscape over time and eventually transition to lower energy states as compared to the frozen-in configurations obtained upon cooling from above the Curie temperature. Thus, this materials system allows for a facile method to systematically study thermal evolution of artificial spin ice arrays of nano-islands at temperatures modestly above room temperature.

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Source: https://tomesphere.com/paper/1705.02309