Large perpendicular magnetic anisotropy at Fe/rock-salt-type Cr-oxide interface synthesized via oxygen-driven chemical layer exchange process

Yuki Iida; Qingyi Xiang; Thomas Scheike; Zhenchao Wen; Jun Okabayashi; Jun Uzuhashi; Tadakatsu Ohkubo; Kazuhiro Hono; Hiroaki Sukegawa; Seiji Mitani

doi:10.1063/5.0233103

論文 Large perpendicular magnetic anisotropy at Fe/rock-salt-type Cr-oxide interface synthesized via oxygen-driven chemical layer exchange process

Yuki Iida ; Qingyi Xiang ; Thomas Scheike ; Zhenchao Wen ; Jun Okabayashi ; Jun Uzuhashi ; Tadakatsu Ohkubo ; Kazuhiro Hono ; Hiroaki Sukegawa ; Seiji Mitani

137-APL Mater. 12, 111116 (2024)-Iida.pdf

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Yuki Iida, Qingyi Xiang, Thomas Scheike, Zhenchao Wen, Jun Okabayashi, Jun Uzuhashi, Tadakatsu Ohkubo, Kazuhiro Hono, Hiroaki Sukegawa, Seiji Mitani. Large perpendicular magnetic anisotropy at Fe/rock-salt-type Cr-oxide interface synthesized via oxygen-driven chemical layer exchange process. APL Materials. 2024, 12 (11), . https://doi.org/10.1063/5.0233103

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Perpendicular magnetic anisotropy (PMA) induced at the interface of the metallic magnetic layer/oxide layer plays a major role in scaling of state-of-the-art spin-transfer-torque magnetoresistive random access memory. The realization of PMA requires the development of mature interface manipulation techniques, as well as materials constituting the interface. Herein, we report large PMA using stacks developed with an ultrathin (~0.7 nm) Fe/rock-salt CrO(001) interface via an oxygen-driven diffusion process. The stacks were prepared by sputter-deposition and post-annealing of the Cr buffer/ultrathin Fe/MgO structure. Significant oxidation of the Fe layer and Cr diffusion into the MgO layer occurred during the deposition. After post-annealing, the oxidized Fe layer was reduced to form an Fe/rock-salt-type Cr-monoxide structure due to chemical layer exchange. The lattice-matched Fe/CrO interface with a large interfacial PMA energy of 1.55 mJ/m2 was confirmed after annealing at 500degreeC. X-ray absorption spectroscopy measurements revealed that the post-annealing promoted the redox reaction from the Fe oxide to the metallic Fe and the formation of the CrO. The observed PMA indicates that the oxygen-driven diffusion process by annealing resulted in the well-controlled Fe/CrO interface. The demonstrated diffusion process provides a new chemical route to fabricate artificial, well-controlled PMA interfaces, even containing metastable materials, beyond the conventional sequential layer stacking for the development of spintronic devices.

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