High‐temperature strength of liquid‐phase‐sintered silicon carbide ceramics: A review

Maity, Taraknath; Kim, Young‐Wook

doi:10.1111/ijac.13805

Cited by 27 publications

(14 citation statements)

References 137 publications

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“…Therefore, it is a widely used method for the fabrication of SiC and SiC‐based ceramic matrix composites 6 . However, even though the liquid‐phase sintering additives are employed, sintering temperatures in the range of 1700–2100°C are usually required to consolidate SiC ceramics to near fully density 6,16 . On the other hand, the mechanical properties of SiC fibers are significantly deteriorated at temperatures above 1500°C, due to the grain growth of SiC fibers 25–27 .…”

Section: Introductionmentioning

confidence: 99%

“…7 Therefore, various sintering additives have been employed to improve consolidation of SiC, including both the solid-state sintering additives, such as B 4 C-C, B-C, and Al-B-C, [8][9][10] and the liquid-phase sintering additives, such as Al 2 O 3 , AlN, and rare-earth oxides (RE 2 O 3 ). [11][12][13][14][15][16][17] Liquid-phase sintering additives have been proven to be more efficient, due to a significantly higher diffusion rate of atoms achieved in a liquid when compared to a solid.…”

Section: Introductionmentioning

confidence: 99%

“…6 However, even though the liquid-phase sintering additives are employed, sintering temperatures in the range of 1700-2100 • C are usually required to consolidate SiC ceramics to near fully density. 6,16 On the other hand, the mechanical properties of SiC fibers are significantly deteriorated at temperatures above 1500 • C, due to the grain growth of SiC fibers. [25][26][27] Hence, the sintering temperature of SiC-based ceramic matrix composites should be as low as possible to inhibit the grain growth of SiC fibers.…”

Section: Introductionmentioning

confidence: 99%

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Low‐temperature Pr₃Si₂C₂‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Zhou

Zou

et al. 2022

J Am Ceram Soc.

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A novel Pr 3 Si 2 C 2 additive was uniformly coated on SiC particles using a moltensalt method to fabricate a high-density SiC ceramics via liquid-phase spark plasma sintering at a relatively low temperature (1400 • C). According to the calculated Pr-Si-C-phase diagram, the liquid phase was formed at ∼1217 • C, which effectively improved the sintering rate of SiC by the solution-reprecipitation process. When the sintering temperature increased from 1400 to 1600 • C, the thermal conductivity of SiC increased from 84 to 126 W/(m K), as a consequence of the grain growth. However, an increasing amount of the sintering additive increased the interfacial thermal resistance, resulting in a decrease of thermal conductivity of the materials. The highest thermal conductivity of 141 W/(m K) was obtained for the material having the largest SiC grains and an optimized amount of the additive at the grain boundaries and triple junctions. The proposed Pr 3 Si 2 C 2assisted liquid-phase sintering of SiC can be potentially used for the fabrication of SiC-based ceramic composites, where a low sintering temperature would inhibit the grain growth of SiC fibers.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Low‐temperature Pr₃Si₂C₂‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Zhou

Zou

et al. 2022

J Am Ceram Soc.

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“…[1][2][3] Owing to these advantages, SiC is one of the most important structural ceramics used in heat exchangers, gas turbine components, and accident-tolerant fuel cladding in light-water reactors. [4][5][6][7] However, conventional SiC ceramics have high electrical resistivity, hardness, and brittleness, which makes the processing of complex components difficult. Materials with low-electrical resistivity (<100 Ω cm) can be efficiently machined with high precision into complex surfaces through electric discharge machining (EDM).…”

Section: Introductionmentioning

confidence: 99%

Microstructural, electrical, and mechanical properties of conductive SiC ceramics fabricated by spark plasma sintering

Shen

Yang

et al. 2022

Int J Applied Ceramic Tech

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Nitrogen (N)-doped conductive silicon carbide (SiC) of various electrical resistivity grades can satisfy diverse requirements in engineering applications. To understand the mechanisms that determine the electrical resistivity of N-doped conductive SiC ceramics during the fast spark plasma sintering (SPS) process, SiC ceramics were synthesized using SPS in an N 2 atmosphere with SiC powder and traditional Al 2 O 3 -Y 2 O 3 additive as raw materials at a sintering temperature of 1850-2000 • C for 1-10 min. The electrical resistivity was successfully varied over a wide range of 10 −3 -10 1 Ω cm by modifying the sintering conditions. The SPS-SiC ceramics consisted of mainly Y-Al-Si-O-C-N glass phase and N-doped SiC. The Y-Al-Si-O-C-N glass phase decomposed to an Si-rich phase and Ndoped Y x Si y C z at 2000 • C. The Vickers hardness, elastic modulus, and fracture toughness of the SPS-SiC ceramics varied within the ranges of 14.35-25.12 GPa, 310.97-400.12 GPa, and 2.46-5.39 MPa m 1/2 , respectively. The electrical resistivity of the obtained SPS-SiC ceramics was primarily determined by their carrier mobility.

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“…Currently, most of the ceramics are produced by molding raw powder, followed by sintering. [1][2][3][4][5][6][7][8][9][10][11] During powder processing, sintering is caused via dynamic mass transfer, resulting in densification and microstructure development. Therefore, understanding and controlling sintering is extremely important for producing better ceramics.…”

Section: Introductionmentioning

confidence: 99%

In situ observation of evolution of internal structure of alumina during sintering by swept‐source OCT

Takahashi

Sakamoto

Tatami

et al. 2021

Int J Applied Ceramic Tech

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In situ observation of sintering of ceramics is important to understand the sintering behavior, including the development of internal structures, and to fabricate ceramics with superior properties. However, there has been no studies thus far on high‐speed in situ observation of the internal structure of green and sintered bodies at high temperatures with micrometer‐scale resolution. Here, we applied swept‐source optical coherence tomography (OCT) to observe the evolution of the internal structure in Al2O3 green bodies during sintering. In situ OCT observations revealed that internal structure changes during sintering, such as the development of density distribution and growth of coarser pores. We could also obtain the sintering shrinkage ratio and relative density from the OCT images. The OCT observation of the internal structure during sintering of green bodies with added or stacked granules of different primary particle sizes confirmed that inhomogeneous regions developed as the densification progressed at high temperatures. These results indicate that in situ observation of the sintering behavior of ceramic green bodies using swept‐source OCT is a novel technique that facilitates real‐time observation of the evolution of the internal structure during sintering.

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High‐temperature strength of liquid‐phase‐sintered silicon carbide ceramics: A review

Cited by 27 publications

References 137 publications

Low‐temperature Pr₃Si₂C₂‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Low‐temperature Pr₃Si₂C₂‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Microstructural, electrical, and mechanical properties of conductive SiC ceramics fabricated by spark plasma sintering

In situ observation of evolution of internal structure of alumina during sintering by swept‐source OCT

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High‐temperature strength of liquid‐phase‐sintered silicon carbide ceramics: A review

Cited by 27 publications

References 137 publications

Low‐temperature Pr3Si2C2‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Low‐temperature Pr3Si2C2‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Microstructural, electrical, and mechanical properties of conductive SiC ceramics fabricated by spark plasma sintering

In situ observation of evolution of internal structure of alumina during sintering by swept‐source OCT

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Product

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Low‐temperature Pr₃Si₂C₂‐assisted liquid‐phase sintering of SiC with improved thermal conductivity

Low‐temperature Pr₃Si₂C₂‐assisted liquid‐phase sintering of SiC with improved thermal conductivity