Effect of activating additives on the cold sintering process of (MnFeCoNiCu)3O4 high-entropy ceramics
A. V. Smirnov,
Yu. D. Ivakin,
M. V. Kornyushin,
A. A. Kholodkova,
A. A. Vasin,
S. Ayudinyan,
H. V. Kirakosyan https://doi.org/10.32362/2410-6593-2022-17-5-439-449
Abstract
Objectives. To obtain experimental data on the effect of activating additive type on the cold sintering process of (MnFeCoNiCu)3O4 high-entropy ceramic. The following substances were used as activating additives: ammonium acetate (CH3COONH4), acetic acid (CH3COOH), ammonium chloride (NH4Cl), potassium fluoride dihydrate (КF·2H2O), lithium fluoride (LiF), sodium fluoride (NaF), and sodium hydroxide (NaOH).
Methods. Synthesis of the initial powder by low-temperature self-propagating method; investigation of the powder particles size distribution by laser diffraction method; analysis of the particle shape and compacted sample microstructure by scanning electron microscopy; investigation of the phase composition by X-ray phase analysis; high-entropy ceramic sample consolidation by cold sintering process. The density of the initial powder and the relative density of cold sintered samples were determined by the Archimedes method.
Results. Samples with a relative density of over 0.70 were obtained using distilled water, CH3COONH4 and NaOH during cold sintering at 300 °C, with a holding time of 30 min and pressure 315 MPa.
Conclusions. For the first time, the effect of the type of activating additive on the relative density of high-entropy ceramics (MnFeCoNiCu)3O4 samples obtained by cold sintering process has been experimentally demonstrated. The samples microstructures have pronounced differences: 20 wt % distilled water does not lead to grain growth, with only their compaction to 0.71 relative density observed; however, the addition of 0.1 wt % CH3COONH4 and NaOH increases the average grain size when reaching similar relative densities (0.70 and 0.71, respectively). X-ray diffraction analysis showed that the cold sintering process does not lead to a change in the phase composition of the initial (MnFeCoNiCu)3O4 powder, confirming the preservation of the high-entropy structure.
Keywords
Supporting agencies: The study was supported by the Ministry of Science and Higher Education of the Russian Federation, Agreement No. 075-15-2021-974 of September 28, 2021. The applied research was conducted on the topic of “Development of technological methods for reducing the sintering temperature of high-entropy ceramic materials based on transition metal oxides.” The work was carried out with the use of equipment of the Joint Educational and Scientific Center for Collective Use at the MIREA – Russian Technological University and the Center for Collective Use “High-Tech Technologies of Mechanical Engineering” at the Moscow Polytechnic University. Also, the work was supported by the Science Committee of the Ministry of Education, Science, Culture and Sports of the Republic of Armenia, the research project No. 20TTWS-2F040.
About the Authors
A. V. Smirnov
Mobile Solutions Engineering Center, MIREA – Russian Technological University
Russian Federation
Russian Federation
Andrey V. Smirnov, Cand. Sci. (Eng.), Head of the Department of Advanced Materials Technologies
78, Vernadskogo pr., Moscow, 119454
ResearcherID J-2763-2017
Scopus Author ID 56970389000
RSCI SPIN-code 2919-9250
Yu. D. Ivakin
Mobile Solutions Engineering Center, MIREA – Russian Technological University; Faculty of Chemistry, M.V. Lomonosov Moscow State University
Russian Federation
Russian Federation
Yuri D. Ivakin, Cand. Sci. (Chem.), Senior Researcher, Department of Physical Chemistry
1-3, Kolmogorova ul., Moscow, 119234
ResearcherID N-9483-2013
Scopus Author ID 6603058433
RSCI SPIN-code 7337-4173
M. V. Kornyushin
Mobile Solutions Engineering Center, MIREA – Russian Technological University
Russian Federation
Russian Federation
Maxim V. Kornyushin, Engineer, Laboratory of Ceramic and Composite Materials
78, Vernadskogo pr., Moscow, 119454
Scopus Author ID 57219230569
RSCI SPIN-code 7995-3408
A. A. Kholodkova
Mobile Solutions Engineering Center, MIREA – Russian Technological University; Faculty of Chemistry, M.V. Lomonosov Moscow State University
Russian Federation
Russian Federation
Anastasia A. Kholodkova, Cand. Sci. (Chem.), Junior Researcher, Department of Physical Chemistry
1-3, Kolmogorova ul., Moscow, 119234
ResearcherID M-2169-2016
Scopus Author ID 56530861400
RSCI SPIN-code 7256-7784
A. A. Vasin
Mobile Solutions Engineering Center, MIREA – Russian Technological University
Russian Federation
Russian Federation
Alexander A. Vasin, Cand. Sci. (Eng.), Leading Researcher, Laboratory of Ceramic and Composite Materials
78, Vernadskogo pr., Moscow, 119454
ResearcherID К-3214-2015
Scopus Author ID 57211840246
RSCI SPIN-code 3864-9132
S. Ayudinyan
A.B. Nalbandyan Institute of Chemical Physics, National Academy of Sciences
Armenia
Armenia
Sofia Aydinyan, Cand. Sci. (Chem.), Senior Researcher
5/2, P. Sevak ul., Yerevan, 0014
Scopus Author ID 24479551800
H. V. Kirakosyan
A.B. Nalbandyan Institute of Chemical Physics, National Academy of Sciences
Armenia
Armenia
Hasmik V. Kirakosyan, Cand. Sci. (Chem.), Junior Researcher
5/2, P. Sevak ul., Yerevan, 0014
Scopus Author ID 56925595700
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Supplementary files
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Indexing metadata ▾ | |
- The high-entropy ceramic material (MnFeCoNiCu)3O4 synthesized by low-temperature self-propagating synthesis has two phases with the spinel and rock salt structures and it is expected that the material has pronounced magnetic properties.
- When obtaining the (MnFeCoNiCu)3O4 high-entropy ceramics the main task is to preserve the high-entropy structure and the initial phase composition.
- The cold sintering process of the (MnFeCoNiCu)3O4 high-entropy ceramics at 300°C, 30 min dwell time, and 315 MPa pressure using an aqueous medium with additives of 0.1 wt % CH3COONH4 and NaOH does not lead to a change in the phase composition of the initial powder, which indicates the preservation of a highly entropic structure.
Review
For citations:
Smirnov A.V., Ivakin Yu.D., Kornyushin M.V., Kholodkova A.A., Vasin A.A., Ayudinyan S., Kirakosyan H.V. Effect of activating additives on the cold sintering process of (MnFeCoNiCu)3O4 high-entropy ceramics. Fine Chemical Technologies. 2022;17(5):439-449. https://doi.org/10.32362/2410-6593-2022-17-5-439-449
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