Email this article Structural and magnetic properties of the nanocomposite materials based on a mesoporous silicon dioxide matrix
- Authors: Grigor’eva N.A.1, Eckerlebe H.2, Eliseev A.A.3, Lukashin A.V.3, Napol’skii K.S.3, Kraje M.4, Grigor’ev S.V.1,5
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Affiliations:
- St. Petersburg State University
- Helmholtz-Zentrum Geesthacht
- Moscow State University
- Reactor Institute Delft
- B. P. Konstantinov Petersburg Nuclear Physics Institute
- Issue: Vol 124, No 3 (2017)
- Pages: 476-492
- Section: Order, Disorder, and Phase Transition in Condensed System
- URL: https://journals.rcsi.science/1063-7761/article/view/192027
- DOI: https://doi.org/10.1134/S106377611702011X
- ID: 192027
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Abstract
The structural and magnetic properties of the mesoporous systems based on silicon dioxide with a regular hexagonal arrangement of pores several microns in length and several nanometers in diameter, which are filled with iron compound nanofilaments in various chemical states, are studied in detail. The studies are performed using the following mutually complementary methods: transmission electron microscopy, SQUID magnetometry, electron spin resonance, Mössbauer spectroscopy, polarized neutron small-angle diffraction, and synchrotron radiation diffraction. It is shown that the iron nanoparticles in pores are mainly in the γ phase of Fe2O3 with a small addition of the α phase and atomic iron clusters. The effective magnetic field acting on a nanofilament from other nanofilaments is 11 mT and has a dipole nature, the ferromagnetic–paramagnetic transition temperature is in the range 76–94 K depending on the annealing temperature of the samples, and the temperature that corresponds to the change in the magnetic state of the iron oxide nanofilaments is T ≈ 50–60 K at H = 0 and T ≈ 80 K at H = 300 mT. It is also shown that the magnetization reversal of an array of nanofilaments is caused by the magnetostatic interaction between nanofilaments at the fields that are lower than the saturation field.
About the authors
N. A. Grigor’eva
St. Petersburg State University
Author for correspondence.
Email: natali@lns.pnpi.spb.ru
Russian Federation, ul. Ul’yanovskaya 3, Petrodvorets, St. Petersburg, 198504
H. Eckerlebe
Helmholtz-Zentrum Geesthacht
Email: natali@lns.pnpi.spb.ru
Germany, Geesthacht, 2150
A. A. Eliseev
Moscow State University
Email: natali@lns.pnpi.spb.ru
Russian Federation, Moscow, 119991
A. V. Lukashin
Moscow State University
Email: natali@lns.pnpi.spb.ru
Russian Federation, Moscow, 119991
K. S. Napol’skii
Moscow State University
Email: natali@lns.pnpi.spb.ru
Russian Federation, Moscow, 119991
M. Kraje
Reactor Institute Delft
Email: natali@lns.pnpi.spb.ru
Netherlands, Delft, 2629 JB
S. V. Grigor’ev
St. Petersburg State University; B. P. Konstantinov Petersburg Nuclear Physics Institute
Email: natali@lns.pnpi.spb.ru
Russian Federation, ul. Ul’yanovskaya 3, Petrodvorets, St. Petersburg, 198504; ul. Orlova Roshcha 1, Gatchina, Leningradskaya oblast, 188300
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