Study of the initial magnetic permeability of LiTiZnMn ferrites obtained by liquid-phase sintering under radiation-thermal and thermal conditions
DOI:
https://doi.org/10.31489/2023No1/12-19Keywords:
lithium ferrite, liquid-phase sintering, electron beam, high temperature, heating and cooling rates, initial magnetic permeabilityAbstract
The measuring the temperature dependence of the initial permeability was used to study the features of phase and structural transformations in lithium-titanium ferrites as a function of time, heating and cooling rates, and the temperature of liquid-phase sintering under thermal and radiation-thermal heating. Ferrite was synthesized from powder mixture by solid-phase synthesis. A low-melting additive bismuth dioxide was used to obtain the ferrite ceramics by liquid-phase sintering. RT sintering was carried out by heating the samples with a pulsed (1.5–2.0) MeV electron beam. It was established that the additive leads to a less defective state of sintered ferrites, while the action of radiation enhances this effect in the early stages of sintering. The regularities of the influence of the heating and cooling rates of compacted samples on the change in the initial magnetic permeability of sintered ferrites are established.
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