JOPSS:検索結果一覧

検索結果：　2 件中 1件目～2件目を表示

発表形式

Initialising ...

選択項目を絞り込む

掲載資料名

Initialising ...

発表会議名

Initialising ...

筆頭著者名

Initialising ...

キーワード

Initialising ...

使用言語

Initialising ...

発行年

Initialising ...

開催年

Initialising ...

論文

Enhancement of domain-wall mobility detected by NMR at the angular momentum compensation temperature

今井正樹; 中堂博之; 松尾衛; 前川禎通; 齊藤英治

Physical Review B, 102(1), p.014407_1 - 014407_5, 2020/07

https://doi.org/10.1103/PhysRevB.102.014407

被引用回数：6 パーセンタイル：38.16(Materials Science, Multidisciplinary)

The angular momentum compensation temperature $T_{rm A}$ of ferrimagnets has attracted much attention because of high-speed magnetic dynamics near $T_{rm A}$ . We show that NMR can be used to investigate domain wall dynamics near $T_{rm A}$ in ferrimagnets. We performed $^{57}$ Fe-NMR measurements on the ferrimagnet HoFeO $_{12}$ with $T_{rm A}$ = 245 K. In a multi-domain state, the NMR signal is enhanced by domain wall motion. We found that the NMR signal enhancement shows a maximum at $T_{rm A}$ in the multi-domain state. The NMR signal enhancement occurs due to increasing domain-wall mobility toward $T_{rm A}$ . We develop the NMR signal enhancement model involves domain-wall mobility. Our study shows that NMR in multi-domain state is a powerful tool to determine $T_{rm A}$ , even from a powder sample and it expands the possibility of searching for angular momentum-compensated materials.

論文

Current-induced modulation of coercive field in the ferromagnetic oxide SrRuO $_{3}$

山ノ内道彦*; 小山田達郎*; 佐藤晃一*; 太田裕道*; 家田淳一

IEEE Transactions on Magnetics, 55(7), p.1400604_1 - 1400604_4, 2019/07

https://doi.org/10.1109/TMAG.2019.2894897

被引用回数：4 パーセンタイル：27.05(Engineering, Electrical & Electronic)

We investigated the coercive field $H_{c}$ for Domain Wall (DW) motion as a function of the current in the ferromagnetic oxide SrRuO $_{3}$ , a model system with narrow DWs for fabricating high-density spintronics devices. The DW is moved by in the direction of the current, and $H_{c}$ is modulated linearly in . This linear relationship is consistent with an effective magnetic field $H_{eff}$ driving the DW. The direction of DW motion and the magnitude of $H_{eff}$ are well described by a model based on the field-like torque arising from the spin relaxation of conduction electrons in the DW.