volume | PIER Journals

Abstract

Hollow nanostructures based on the Fe_100-xCo_x alloy were synthesized in the pores of polymer template matrices based on PET using the electrochemical deposition method. Morphology, elemental composition, and structural features were characterized by scanning electron microscopy, energy dispersive analysis, and X-ray diffractometry. The study of the internal magnetic texture was carried out using Mossbauer spectroscopy. The dependence of the change in structural and magnetic properties from the atomic content of components in nanotube structure is revealed. It is established that the synthesized nanostructures are hollow Fe_100-xCo_x nanotubes with a body-centered cubic crystal structure. The decrease in the unit cell parameter with increasing cobalt concentration is due to the difference in the radii of Fe (1.227 Å) and Co (1.191 Å) atoms. It is established that a random distribution of magnetic moments directions of Fe atoms is observed for Fe₁₀₀Co₀ nanotubes. And magnetic texture along the nanotube axis is observed for Fe_100-xCo_x nanotubes, with an increase in Co atoms concentration. The average angle between the direction of the magnetic moment of iron atoms and the nanotube axis decreases from ϑ = 54.6˚ to ϑ = 24.5˚.

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Dr. Kayrat Kamalovich Kadyrzhanov

Dr. Vyacheslav Serafimovich Rusakov

Dr. Artem Leonidovich Kozlovskiy

Dr. Maxim Vladimirovich Zdorovets

Dr. Egor Yur'evich Kaniukov

Dr. Alena Euhenauna Shumskaya

Dr. Inesh Ergazievna Kenzhina

Dr. Maxim Sergeevich Fadeev