Новый стационарный режим связанных колебаний вихрей в трехслойном спин-трансферном наноосцилляторе при больших значениях токов
- Authors: Антонов Г.И.1, Екомасов Е.Г.1,2, Звездин К.А.3, Пугач Н.Г.4
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Affiliations:
- Уфимский Университет Науки и Технологий
- Башкирский Государственный Педагогический Университет
- Институт общей физики им. А.М. Прохорова РАН
- Национальный исследовательский университет “Высшая Школа Экономики”
- Issue: Vol 125, No 1 (2024)
- Pages: 39-46
- Section: ЭЛЕКТРИЧЕСКИЕ И МАГНИТНЫЕ СВОЙСТВА
- URL: https://journals.rcsi.science/0015-3230/article/view/259711
- DOI: https://doi.org/10.31857/S0015323024010064
- EDN: https://elibrary.ru/ZQWBYS
- ID: 259711
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Abstract
Исследуется влияние большого по величине спин-поляризованного тока на связанную динамику вихрей в спин-трансферных наноосцилляторах диаметром 400 нм. Обнаружены новые стационарные режимы связанных колебаний вихрей как для одинаковых, так и для противоположных полярностей ядер. Изучена зависимость частоты стационарных связанных колебаний магнитных вихрей от величины спин-поляризованного тока. Найденный эффект можно использовать для повышения рабочих частот спин-трансферных наноосцилляторов.
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About the authors
Г. И. Антонов
Уфимский Университет Науки и Технологий
Author for correspondence.
Email: georgij.antonow@yandex.ru
Russian Federation, ул. Заки Валиди, 32, Уфа, 450076
Е. Г. Екомасов
Уфимский Университет Науки и Технологий; Башкирский Государственный Педагогический Университет
Email: georgij.antonow@yandex.ru
Russian Federation, ул. Заки Валиди, 32, Уфа, 450076; ул. Октябрьской революции, 3-а, Уфа, 450008
К. А. Звездин
Институт общей физики им. А.М. Прохорова РАН
Email: georgij.antonow@yandex.ru
Russian Federation, ул. Вавилова, 38, Москва, 119991
Н. Г. Пугач
Национальный исследовательский университет “Высшая Школа Экономики”
Email: georgij.antonow@yandex.ru
Russian Federation, ул. Мясницкая, 20, Москва, 101000
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Supplementary files
Supplementary Files
Action
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JATS XML
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Fig. 1. Trajectory of the vortex center at a current density j = 20×10⁷ A/cm²: (a) in a thick layer, (b) in a thin layer. Points 1 and 2 correspond to the moments of time 0 and 10 ns, respectively.
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Fig. 2. Graph of the dependence of (a) frequency, (b) radius of the stationary mode of vortex motion on current density.
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Fig. 3. The trajectory of the vortex motion at a current density j = 26×10⁷ A/cm² in a thick (a, b) and thin layers (c, d). (a) point 1 – 12 ns, point 2 – 14.3 ns, point 3 – 14.4 ns, point 4 – 15 ns. Points 2 and 3 correspond to the switching moment, (b) continuation of the vortex trajectory in Fig. 2a, here one can see how the vortex reaches a stationary mode after switching the polarity. Point 4 – 15 ns, point 8 – 25 ns; in a thin layer (c, d) the trajectory of the vortex motion at a current density j = 26×10⁷ A/cm². Point 1 – 12 ns, point 2 – 14.3 ns, point 3 – 14.4 ns, point 4 – 15 ns, point 5 – 16 ns, point 6 – 16.1 ns, point 7 – 16.2 ns, point 8 – 25 ns.
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Fig. 4. Dynamic change of the vortex structure in a thick layer, current density j = 26×10⁷ A/cm². Times correspond to points in Fig. 3.
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Fig. 5. Dynamic change of the vortex structure in a thin layer, current density 26×10⁷ A/cm². Times correspond to points in Fig. 3.
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