Отправить статью по E-mail Transport, Magnetic, and Memristive Properties of a Nanogranular (CoFeB)x(LiNbOy)100–x Composite Material
- Авторы: Rylkov V.V.1,2, Nikolaev S.N.1, Demin V.A.1, Emelyanov A.V.1, Sitnikov A.V.3, Nikiruy K.E.1,4, Levanov V.A.1,5, Presnyakov M.Y.1, Taldenkov A.N.1, Vasiliev A.L.1, Chernoglazov K.Y.1, Vedeneev A.S.2, Kalinin Y.E.3, Granovsky A.B.5, Tugushev V.V.1, Bugaev A.S.4,2
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Учреждения:
- National Research Centre “Kurchatov Institute,”
- Fryazino Branch, Kotelnikov Institute of Radio Engineering and Electronics
- Voronezh State Technical University
- Moscow Institute of Physics and Technology
- Moscow State University
- Выпуск: Том 126, № 3 (2018)
- Страницы: 353-367
- Раздел: Order, Disorder, and Phase Transition in Condensed System
- URL: https://journals.rcsi.science/1063-7761/article/view/192911
- DOI: https://doi.org/10.1134/S1063776118020152
- ID: 192911
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Аннотация
The properties of (CoFeB)x(LiNbOy)100–x nanocomposite films with a ferromagnetic alloy content x = 6–48 at % are comprehensively studied. The films are shown to consist of ensembles of CoFe granules 2–4 nm in size, which are strongly elongated (up to 10–15 nm) in the nanocomposite growth direction and are located in an LiNbOy matrix with a high content of Fe2+ and Co2+ magnetic ions (up to 3 × 1022 cm–3). At T ≤ 25 K, a paramagnetic component of the magnetization of nanocomposites is detected along with a ferromagnetic component, and the contribution of the former component is threefold that of the latter. A hysteresis of the magnetization is observed below the percolation threshold up to x ≈ 33 at %, which indicates the appearance of a superferromagnetic order in the nanocomposites. The temperature dependence of the electrical conductivity of the nanocomposites in the range T ≈ 10–200 K on the metallic side of the metal–insulator transition (44 at % < x < 48 at %) is described by a logarithmic law σ(T) ∝ lnT. This law changes into the law of “1/2” at x ≤ 40 at %. The tunneling anomalous Hall effect is strongly suppressed and the longitudinal conductivity turns out to be lower than in a (CoFeB)x(AlOy)100–x composite material by an order of magnitude. The capacitor structures based on (CoFeB)x(LiNbOy)100–x films exhibit resistive switching effects. They are related to (i) the formation of isolated chains of elongated granules and an anomalously strong decrease in the resistance in fields E > 104 V/cm because of the suppression of Coulomb blockage effects and the generation of oxygen vacancies VO and (ii) the injection (or extraction) of VO vacancies (depending on the sign of voltage) into a strongly oxidized layer in the nanocomposites, which is located near an electrode of the structure and controls its resistance. The number of stable resistive switchings exceeds 105 at a resistance ratio Roff/Ron ~ 50.
Об авторах
V. Rylkov
National Research Centre “Kurchatov Institute,”; Fryazino Branch, Kotelnikov Institute of Radio Engineering and Electronics
Автор, ответственный за переписку.
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182; Fryazino, Moscow oblast, 141190
S. Nikolaev
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
V. Demin
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
A. Emelyanov
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
A. Sitnikov
Voronezh State Technical University
Email: vvrylkov@mail.ru
Россия, Voronezh, 394026
K. Nikiruy
National Research Centre “Kurchatov Institute,”; Moscow Institute of Physics and Technology
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182; Institutskii per. 9, Dolgoprudnyi, Moscow oblast, 141700
V. Levanov
National Research Centre “Kurchatov Institute,”; Moscow State University
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182; Moscow, 119991
M. Presnyakov
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
A. Taldenkov
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
A. Vasiliev
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
K. Chernoglazov
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
A. Vedeneev
Fryazino Branch, Kotelnikov Institute of Radio Engineering and Electronics
Email: vvrylkov@mail.ru
Россия, Fryazino, Moscow oblast, 141190
Yu. Kalinin
Voronezh State Technical University
Email: vvrylkov@mail.ru
Россия, Voronezh, 394026
A. Granovsky
Moscow State University
Email: vvrylkov@mail.ru
Россия, Moscow, 119991
V. Tugushev
National Research Centre “Kurchatov Institute,”
Email: vvrylkov@mail.ru
Россия, pl. Kurchatova 1, Moscow, 123182
A. Bugaev
Moscow Institute of Physics and Technology; Fryazino Branch, Kotelnikov Institute of Radio Engineering and Electronics
Email: vvrylkov@mail.ru
Россия, Institutskii per. 9, Dolgoprudnyi, Moscow oblast, 141700; Fryazino, Moscow oblast, 141190
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