# Tunneling Magnetoresistance and Spin-Dependent Diode Performance in   Fully Epitaxial Magnetic Tunnel Junctions with Rock-salt Type ZnO/MgO

**Authors:** Hidekazu Saito, Sai Krishna Narayananellore, Norihiro Matsuo, Naoki, Doko, Shintaro Kon, Yukiko Yasukawa, Hiroshi Imamura, Shinji Yuasa

arXiv: 1906.05981 · 2019-06-17

## TL;DR

This study demonstrates that fully epitaxial Fe/ZnO/MgO/Fe magnetic tunnel junctions with a bilayer barrier achieve high magnetoresistance and diode performance at room temperature, promising for high-frequency rectification applications.

## Contribution

It introduces a novel epitaxial ZnO/MgO bilayer tunnel barrier in magnetic tunnel junctions, enhancing diode responsivity without increasing resistance-area products.

## Key findings

- Achieved up to 96% magnetoresistance ratio at room temperature.
- Observed diode responsivity up to 1.3 A/W at zero bias.
- Identified magnon excitations as key to spin-dependent diode performance.

## Abstract

We fabricate fully epitaxial Fe/ZnO/MgO/Fe magnetic tunnel junctions (MTJs) with a bilayer tunnel barrier, in which ZnO has a metastable rock-salt crystal structure. We observe a high magnetoresistance ratio up to 96% at room temperature (RT) and find that these MTJs have asymmetric current-voltage characteristics, and their rectifying performances are largely dependent on the magnetization alignments of the Fe electrodes. Diode responsibilities at a zero-bias voltage ($\beta_{0}$), which is an important performance index for harvesting applications, are observed up to 1.3 A/W at RT in the antiparallel alignment of the magnetizations while maintaining rather low resistance-area (RA) products (a few tens of k${\Omega\mu}$m$^2$). Even with the same top and bottom electrodes (Fe), the obtained $\beta_{0}$ values are comparable to those of reported high-performance tunnel diodes consisting of amorphous bilayer tunnel barriers with polycrystalline dissimilar electrodes. This strongly suggests that the epitaxial ZnO/MgO bilayer tunnel barrier is effective for enhancing the $\beta_{0}$ without significant increase in the RA. In addition, we demonstrate that a zero-bias anomaly in thetunnel conductance, which originates from the magnon excitations at the Fe/barrier interfaces, plays a crucial role in observed spin-dependent diode performance. The results indicate that a fully epitaxial MTJ with a bilayer tunnel barrier is a promising candidate to establish a high-performance high-frequency rectifying system.

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Source: https://tomesphere.com/paper/1906.05981