Relationship between magnetic properties and microstructure of ferrites during sintering in radiation and radiation-thermal conditions / A. V. Malyshev, E. N. Lysenko, E. A. Sheveleva [et al.]

Set Level: Eurasian Physical Technical JournalCoauthor: Malyshev, A. V., Specialist in the field of electrical engineering, Senior researcher at Tomsk Polytechnic University, Candidate of Physics and Mathematics (PhD Phys.-Math.), 1978-, Andrei Vladimirovich;Lysenko, E. N., Specialist in the field of electrical engineering, Professor of Tomsk Polytechnic University, Doctor of technical sciences, 1972-, Elena Nikolaevna;Sheveleva, E. A., specialist in the field of electrical engineering, Associate Professor of Tomsk Polytechnic University, Candidate of technical sciences, 1975-, Elena Aleksandrovna;Surzhikova, O. A., Olga Anatoljevna;Aryngazin, A. K., Askar KanapjevichCorporate Author (Secondary): Национальный исследовательский Томский политехнический университет, Инженерная школа неразрушающего контроля и безопасности, Отделение контроля и диагностикиLanguage: английский.Country: Kazakhstan.Abstract: The studies of correlation between magnetic properties and microstructure were conducted on samples of lithium-substituted ferrite, sintered in radiation and radiation-thermal conditions. Radiation-thermal sintering was performed for compacts irradiated with a pulsed electron beam with energy of (1.5-2.0) MeV, beam current per pulse of (0.5-0.9) A, irradiation pulse duration of 500 μs, pulse repetition rate of (5-50) Hz, and compact heating rate of 1000 °C/min. Sintering in thermal furnaces (T-sintering) was carried out in a preheated chamber electric furnace. The paper shows that magnetic induction does not depend on the ferrite grain size. In this case, the coercive force is inversely proportional to the grain size and depends on the intragranular porosity of ferrite samples. In contrast to thermal sintering, radiation-thermal sintering does not cause capturing of intergranular voids by growing grains and enhances coagulation of intragranular pores..Bibliography: [References: 32 tit.].Subject: электронный ресурс | труды учёных ТПУ | ferrites | sintering | magnetic properties | microstructure | intense electron beams | high temperatures | ферриты | спекание | магнитные свойства | микроструктуры | интенсивные пучки | электронные пучки | высокие температуры Online Resources:Click here to access online | Click here to access online
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[References: 32 tit.]

The studies of correlation between magnetic properties and microstructure were conducted on samples of lithium-substituted ferrite, sintered in radiation and radiation-thermal conditions. Radiation-thermal sintering was performed for compacts irradiated with a pulsed electron beam with energy of (1.5-2.0) MeV, beam current per pulse of (0.5-0.9) A, irradiation pulse duration of 500 μs, pulse repetition rate of (5-50) Hz, and compact heating rate of 1000 °C/min. Sintering in thermal furnaces (T-sintering) was carried out in a preheated chamber electric furnace. The paper shows that magnetic induction does not depend on the ferrite grain size. In this case, the coercive force is inversely proportional to the grain size and depends on the intragranular porosity of ferrite samples. In contrast to thermal sintering, radiation-thermal sintering does not cause capturing of intergranular voids by growing grains and enhances coagulation of intragranular pores.

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