Spark Plasma Sintering of Paper-Derived Ti3AlC2-Based Composites: Influence of Sintering Temperature; Materials Science Forum; Vol. 1016 : THERMEC’2020/2021
| Parent link: | Materials Science Forum: Scientific Journal Vol. 1016 : THERMEC’2020/2021.— 2021.— [P. 1790-1796] |
|---|---|
| Corporate Authors: | , |
| Outros autores: | , , , |
| Summary: | Title screen This paper describes the influence of sintering temperature on phase composition and microstructure of paper-derived Ti3AlC2 composites fabricated by spark plasma sintering. The composites were sintered at 100 MPa pressure in the temperature range of 1150-1350 °C. Phase composition and microstructure were analyzed by X-ray diffraction and scanning electron microscopy, respectively. The multiphase structure was observed in the sintered composites consisting of Ti3AlC2, Ti2AlC, TiC and Al2O3 phases. The decomposition of the Ti3AlC2 phase into Ti2AlC and TiC carbide phases was observed with temperature rise. The total content of Ti3AlC2 and Ti2AlC phases was reduced from 84.5 vol.% (1150 °C) to 69.5 vol.% (1350 °C). The density of composites affected by both the content of TiC phase and changes in porosity. Режим доступа: по договору с организацией-держателем ресурса |
| Idioma: | inglés |
| Publicado: |
2021
|
| Subjects: | |
| Acceso en liña: | https://doi.org/10.4028/www.scientific.net/MSF.1016.1790 |
| Formato: | MixedMaterials Electrónico Capítulo de libro |
| KOHA link: | https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=663723 |
Títulos similares
Preceramic paper-derived Ti3Al(Si)C2-based composites obtained by spark plasma sintering; Ceramics International; Vol. 47, iss. 9
Publicado: (2021)
Publicado: (2021)
Spark plasma sintering of Nb/Ti3Al(Si)C2-TiC laminated composites; Materialia; Vol. 27
Publicado: (2023)
Publicado: (2023)
Preceramic paper derived Ti3AlC2 – TiC – Al2O3 composites obtained via spark plasma sintering; Materials Letters; Vol. 409
Publicado: (2026)
Publicado: (2026)
Fabrication of Paper-Derived Ti3SiC2-Based Materials by Spark Plasma Sintering; Advanced Engineering Materials; Vol. 22, iss. 6
Publicado: (2020)
Publicado: (2020)
Functionally graded laminated composites fabricated from MAX-phase filled preceramic papers: Microstructure, mechanical properties and oxidation resistance; Journal of the European Ceramic Society; Vol. 42, iss. 5
Publicado: (2022)
Publicado: (2022)
Microstructure and Phase Composition of Porous SiC-Ceramic Obtained by Spark Plasma Sintering of Preceramic Paper; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 17
por: Sedanova E. P. Elizaveta Pavlovna
Publicado: (2023)
por: Sedanova E. P. Elizaveta Pavlovna
Publicado: (2023)
Влияние соотношения толщины керамического к металлическому слою на механические свойства ламинированных композитов на основе Ta/Ti3Al(Si)C2-TiC-Al2O3; Перспективы развития фундаментальных наук; Т. 1 : Физика
por: Ляхова А. А.
Publicado: (2025)
por: Ляхова А. А.
Publicado: (2025)
Microstructure and Deformation Behavior of Novel Metal–Ceramic Laminated Composites Ta/Ti3Al(Si)C2–TiC; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 18
Publicado: (2024)
Publicado: (2024)
Improved mechanical and thermal properties of quasi-ductile metal-ceramic laminated composites produced from Ta foils and Ti3Al(Si)C2 filled preceramic paper; Ceramics International; Vol. 51, iss. 23
Publicado: (2025)
Publicado: (2025)
Porous SiC ceramic obtained by spark plasma sintering of preceramic paper: Microstructure, mechanical properties and gas permeability; Ceramics International; Vol. 50, iss. 8
Publicado: (2024)
Publicado: (2024)
Preceramic Paper-Derived SiCf/SiCp Composites Obtained by Spark Plasma Sintering: Processing, Microstructure and Mechanical Properties; Materials; Vol. 13 iss. 3
Publicado: (2020)
Publicado: (2020)
High Toughness Laminated Composites Fabricated from Ti3Al(Si)C2 Filled Preceramic Paper and Nb Foils: Formation Mechanism and Influence of Laminate Architecture; Advanced Engineering Materials; Vol. 26, iss. 13
Publicado: (2024)
Publicado: (2024)
Ti3SiC2 MAX-Phase-Based Composites Produced by Vacuum and Spark Plasma Sintering; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 19, iss. 5
Publicado: (2025)
Publicado: (2025)
Paper-Derived Ferroelectric Ceramics: A Feasibility Study; Advanced Engineering Materials; Vol. 20, iss. 7
Publicado: (2018)
Publicado: (2018)
Synthesis of MAX-Phase Ti3SiC2 by Combined Powder Metallurgy Technique; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 18, iss. 6
Publicado: (2024)
Publicado: (2024)
Preceramic paper-derived SiCf/Ti3Al(Si)C2 and SiCf/Ti3SiC2 MAX-phase based laminates fabricated using spark plasma sintering; Scripta Materialia; Vol. 194
Publicado: (2021)
Publicado: (2021)
Сравнительный анализ структурно-фазового состояния и механических свойств композитов Nb/Ti₃Al(Si)C₂-TiC-Al₂O₃, полученных искровым плазменным спеканием и горячим прессованием; Перспективы развития фундаментальных наук; Т. 2 : Химия
por: Абдульменова А. В.
Publicado: (2025)
por: Абдульменова А. В.
Publicado: (2025)
Al2O3/Cu-O composites fabricated by pressureless infiltration of paper-derived Al2O3 porous preforms; Ceramics International; Vol. 44, iss. 17
Publicado: (2018)
Publicado: (2018)
Influence of selective laser treatment on thermal stability of Ti3AlC2 and Ti3AlC2/Cu powders; Materials Letters; Vol. 309
Publicado: (2022)
Publicado: (2022)
Macrostructure and Strength of the Al–Zn–Sn Composite Produced by Liquid-Phase Sintering of the Al–Zn Alloy and Pure Tin Powder Mixture; Russian Journal of Non-Ferrous Metals; Vol. 60, iss. 3
por: Rusin N. M. Nikolay Martemjyanovich
Publicado: (2019)
por: Rusin N. M. Nikolay Martemjyanovich
Publicado: (2019)
Laminated Object Manufacturing of Ceramic-Based Materials; Advanced Engineering Materials; Vol. 22, iss. 9
por: Dermeik B. Benjamin
Publicado: (2020)
por: Dermeik B. Benjamin
Publicado: (2020)
Phase transformations in ferrites during radiation-thermal sintering; Eurasian Physical Technical Journal; Vol. 17, № 1 (33)
Publicado: (2020)
Publicado: (2020)
Interaction of metals and alloys with gas media under spark discharges; Resource-Efficient Technologies; No 3
Publicado: (2018)
Publicado: (2018)
The densification process and microstructure of the B4C/ultra-high molecular weight polyethylene composites consolidated by spark plasma sintering; Ceramics International; Vol. 51, iss. 30
Publicado: (2025)
Publicado: (2025)
Окислительное поведение ламинированных композитов Nb/Ti3Al(Si)C2-TiC при высоких температурах; Перспективы развития фундаментальных наук; Т. 1 : Физика
por: Абдульменова А. В. Анастасия Владимировна
Publicado: (2024)
por: Абдульменова А. В. Анастасия Владимировна
Publicado: (2024)
Experimental Study of Laser Treatment of Ti3AlC2 Max Phase; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Publicado: (2020)
Publicado: (2020)
Механохимический синтез интерметаллического соединения TiFe из элементарных порошков железа и титана; Перспективы развития фундаментальных наук; Т. 2 : Химия
por: Михня М. Ю.
Publicado: (2024)
por: Михня М. Ю.
Publicado: (2024)
Effects of sintering curves on microstructure, physical and mechanical properties and on low temperature degradation of zirconia-toughened alumina; Journal of the European Ceramic Society; Vol. 41, iss. 16
Publicado: (2021)
Publicado: (2021)
Microstructure and Phase Composition of 3D Printed Titanium Metal Matrix Composites Based on Ti-Al-V-Fe System and Reinforced with TiC Particles; Russian Physics Journal; Vol. 67, iss. 9
Publicado: (2024)
Publicado: (2024)
Characterization and densification of hot pressed ZrCN-ZrO2 ceramics; Science of Sintering; Vol. 57, iss. 4
Publicado: (2025)
Publicado: (2025)
Studying the Moulding Ways for the Metal Powdered Aluminum Reinforced with Carbon Fiber in the Spark Plasma Sintering Process; Key Engineering Materials; Vol. 769 : High Technology: Research and Applications (HTRA 2017)
Publicado: (2018)
Publicado: (2018)
In Situ High-Temperature Synchrotron X-ray Studies of Microstructure and Phase Composition of Additively Fabricated Ti–6Al–4V/TiC Metal Matrix Composite; Journal of Surface Investigation: X-ray, Synchrotron and Neutron Techniques; Vol. 19, iss. 4
Publicado: (2025)
Publicado: (2025)
Spark plasma sintering of ceramics based on silicon nitride and titanium nitride; 11th International Forum on Strategic Technology (IFOST 2016); Pt. 1
Publicado: (2016)
Publicado: (2016)
Формирование композитов с алюминиевой матрицей, армированных наночастицами карбида вольфрама; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 335, № 3
Publicado: (2024)
Publicado: (2024)
Manufacturing Optically Transparent Thick Zirconia Ceramics by Spark Plasma Sintering with the Use of Collector Pressing; Applied Sciences; Vol. 11, iss. 3
Publicado: (2021)
Publicado: (2021)
Получение объемных изделий из металломатричного композита Cu-SiC для энергоэффективных теплопроводящих систем; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 334, № 7
Publicado: (2023)
Publicado: (2023)
Features of the Synthesis of TiCAl (Fe2O3/TiO2) Metal Matrix Composites under Nonequilibrium Conditions; Energy Fluxes and Radiation Effects (EFRE-2020 online)
por: Knyazeva A. G. Anna Georgievna
Publicado: (2020)
por: Knyazeva A. G. Anna Georgievna
Publicado: (2020)
Features of heterophase structure formation at spark plasma sintering of high-carbon and chromium-nickel steels; Materials Characterization; Vol. 129
por: Nikulina A. A.
Publicado: (2017)
por: Nikulina A. A.
Publicado: (2017)
Comparative Evaluation of Spark Plasma and Conventional Sintering of NiO/YSZ Layers for Metal-Supported Solid Oxide Fuel Cells; High Temperature Materials and Processes; Vol. 37, iss. 4
Publicado: (2018)
Publicado: (2018)
High-Temperature Plasma Sintering of the Mixture of Different Fractions of the Plasmadynamic Synthesis Product; Russian Physics Journal; Vol. 61, No. 4
por: Evdokimov A. A. Andrey Anatoljevich
Publicado: (2018)
por: Evdokimov A. A. Andrey Anatoljevich
Publicado: (2018)