Steklo i Keramika (Glass and Ceramics). Monthly scientific, technical and industrial journal

 

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The results of a study of the dielectric properties and harmonic coefficient for barium titanate ceramics obtained from a powder with a particle size of 50 nm at different sintering temperatures are presented. It is shown that ceramics from nanopowders can be produced at lower sintering temperatures than technical ceramics with a particle size of 1 µm. Ceramics obtained at a sintering temperature of 1200 ?C have the best linear and nonlinear dielectric properties.
Sergey V. Baryshnikov – Doctor of Physical and Mathematical Sciences, Professor, Professor of the Department of Physical and Mathematical Education, Blagoveshchensk State Pedagogical University (BSPU), Blagoveshchensk, Russia
Alexey Yu. Milinsky – Doctor of Physical and Mathematical Sciences, Associate Professor Professor of the Department of Physical and Mathematical Education, Blagoveshchensk State Pedagogical University (BSPU), Blagoveshchensk, Russia
Elena V. Stukova – Doctor of Physical and Mathematical Sciences, Associate Professor, Professor of the Department of Physics, Amur State University (AmSU), Blagoveshchensk, Russia
1. Saravanan R. Titanate based ceramic dielectric materials. Millersville: Materials Research Foundations, 2018. V. 25. 168 p.
2. Somiya S., Komarneni S., Roy R. Ceramic powders for advanced ceramics: what are ideal ceramic powders for advanced ceramics? // Handbook of Advanced Ceramics: Materials, Applications, Processing, and Properties: Second Edition. Elsevier Inc., 2013. V. 35, No. 3. P. 863 – 881.
3. Yun H. S., Kim H. H., Jeong D. Y., Cho N. H. Effects of initial powder size on the densification of barium titanate ceramics prepared by microwave-assisted sintering // J. Am. Ceram. Soc. 2015. V. 98, No. 4. P. 1087 – 1094.
4. Tan Y., Zhang, J., Wu Y., et al. Unfolding grain size effects in barium titanate ferroelectric ceramics // Sci. Rep. 2015. V. 5, No. 1. P. 15 – 21.
5. Curecheriu L., Balmus S.-B., Buscaglia M. T., et al. Grain size-dependent properties of dense nanocrystalline barium titanate ceramics // J. Am. Ceram. Soc. 2012. V. 95, No. 31208. P. 3912 – 3921.
6. Guo H., Baker A., Guo J., Randall C. Protocol for ultralow-temperature ceramic sintering: an integration of nanotechnology and the cold sintering process // ACS Nano. 2016. V. 10, No. 11. P. 10606 ? 10614.
7. Лайнс М., Гласс А. Сегнетоэлектрики и родственные им материалы / пер. с англ., под ред. В. В. Леманова, Г. А. Смоленского. М.: Мир, 1981. 736 с.
8. Ikeda S., Kominami H., Koyama K., Wada Y. Nonlinear dielectric constant and ferroelectric-to-paraelectric phase transition in copolymers of vinylidene fluoride and trifluoroethylene // J. Appl. Phys. 1987. V. 62, No. 8. Р. 3339 – 3342.
9. Юдин С. Г., Блинов Л. М., Петухова Н. Н., Палто С. П. Сегнетоэлектрический фазовый переход в пленках Ленгмюра–Блоджетт фталоцианина меди // Письма в ЖЭТФ. 1999. Т. 70, вып. 9. С. 625 – 631.
10. Старков А. С., Старков И. А. Зависимость диэлектрической проницаемости и электрокалорического эффекта от размера гранулы сегнетоэлектрической керамики // ЖЭТФ. 2023. Т. 163, вып. 5. С. 682 – 697.

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DOI: 10.14489/glc.2024.04.pp.021-028
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Baryshnikov S. V., Milinsky A. Y., Stukova E. V. Linear and nonlinear dielectric properties of ceramics obtained from barium titanate nanopowder. Steklo i keramika. 2024:97(04):21-28. (in Russ). DOI: 10.14489/glc.2024.04.pp.021-028