2018年第65回応用物理学会春季学術講演会

講演情報

一般セッション(口頭講演)

CS コードシェアセッション » CS6 10.1 新物質・新機能創成(作製・評価技術),10.2 スピン基盤技術・萌芽的デバイス技術,10.3 スピンデバイス・磁気メモリ・ストレージ技術のコードシェアセッション

[19p-D104-1~6] CS6 10.1 新物質・新機能創成(作製・評価技術),10.2 スピン基盤技術・萌芽的デバイス技術,10.3 スピンデバイス・磁気メモリ・ストレージ技術のコードシェアセッション

2018年3月19日(月) 13:00 〜 14:30 D104 (56-104)

介川 裕章(物材機構)

13:45 〜 14:00

[19p-D104-4] Enhancement of spin-orbit torque in Co/CoOx/Pt structures

Kento Hasegawa1、Yuki Hibino1、Tomohiro Koyama1、Daichi Chiba1 (1.Univ. of Tokyo)

キーワード:spin-orbit torque, oxidization, spin current

  Enhancement of current-induced torques on magnetization, including spin-orbit torque (SOT) in ferromagnet/heavy-metal bilayer structure, is crucial for magnetic memories operating with an electrical current. Our group has previously reported the enhancement of the field-like (FL) SOT in a Pt/Co system by oxidizing the Co surface (Pt/Co/CoOx structures). In this study, the effect of the oxidation was investigated using Co/CoOx/Pt structures, in which the Pt layer as a spin current source was directly deposited on the oxidized Co surface, to understand the role of the oxidized interface.
  Ta(3.0 nm)/Pd(3.0)/Co(tCo) structures were deposited from the bottom side on the thermally oxidized Si substrate. Subsequently, the Co surface was exposed to the air in order to form CoOx layer (oxidized sample). After that, the 2.7-nm thick Pt layer was deposited onto it. From the measurement of the saturation magnetic moment, the CoOx thickness in this study was determined to be ~0.8 nm. The similar structure without CoOx layer (un-oxidized sample) was also prepared as a reference.
  SOTs in un-oxidized and oxidized samples with several Co thickness were determined by the harmonic Hall voltage measurement. As a result, the DL torque for the oxidized sample was clearly larger than that for the un-oxidized sample even though the CoOx layer existed between the Co and Pt layers. We also confirmed that the FL torque was larger in the oxidized sample. The enhancement of the SOT by inserting the oxidization layer to the interface of the ferromagnet/heavy-metal bilayer structure is expected to provide a new information on the physics of the SOT.