Consolidation of Nanostructured β‐SiC by Spark Plasma Sintering

Yamamoto, Takakazu; Kitaura, Hidetoshi; Kodera, Yasuhiro; Ishii, Takashi; Ohyanagi, Manshi; Munir, Zuhair A.

doi:10.1111/j.1551-2916.2004.01436.x

Cited by 111 publications

(59 citation statements)

References 32 publications

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“…This phenomenon can be explained by the promoting effect of temperature for the growth of crystallites. 15,16 It is interesting to note that when the crystallite size decreases, e.g., for sintering at 8 GPa and 1800°C, the planar defects have significant densities, which again supports the observed correlation between the crystallite size and the defect structure.…”

Section: Resultssupporting

confidence: 60%

“…Statistically equivalent population of threefold and fourfold coordinated atoms has been registered in the outer layers of nanosize SiC grains. 14 The presence of partially disordered structures near the grain boundary has been postulated by Keblinski et al 15 and detected by Yakamoto et al 16 and Liao et al 17 Such structures may facilitate surface diffusion or atom rearrangement during the early stages of the sintering process. The increase of temperature causes the increase of mobility of atoms resulting in faster grain growth.…”

Section: Resultsmentioning

confidence: 98%

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Influence of sintering temperature and pressure on crystallite size and lattice defect structure in nanocrystalline SiC

et al. 2007

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Microstructure of sintered nanocrystalline SiC is studied by x-ray line profile analysis and transmission electron microscopy. The lattice defect structure and the crystallite size are determined as a function of pressure between 2 and 5.5 GPa for different sintering temperatures in the range from 1400 to 1800°C. At a constant sintering temperature, the increase of pressure promotes crystallite growth. At 1800°C when the pressure reaches 8 GPa, the increase of the crystallite size is impeded. The grain growth during sintering is accompanied by a decrease in the population of planar faults and an increase in the density of dislocations. A critical crystallite size above which dislocations are more abundant than planar defects is suggested.

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Section: Resultssupporting

confidence: 60%

Section: Resultsmentioning

confidence: 98%

Influence of sintering temperature and pressure on crystallite size and lattice defect structure in nanocrystalline SiC

et al. 2007

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“…[4] The densification is enhanced by the application of an external mechanical pressure, either uniaxial or isostatic. [3,5] It may be further enhanced by involving a disorder-order phase transformation, [6] by involving a suitable liquid that facilitates the solution-reprecipitation of the major phase, [7] or by allowing deformation to occur during densification, i.e. sinter forging.…”

mentioning

confidence: 99%

“…[5] So far, nanoceramics of SiC, as it is generally defined as ceramics consisting of grains less than 100 nm, have been prepared both by solid-state sintering and by liquid-phase sintering of nano-powders. [3][4][5][6]8] Their record superplastic deformation strain rate is in the order of 1 × 10 -5 /s above 1600°C and of 1 × 10 -4 /s at 1700°C for solid-state sintered and liquidphase sintered SiC nanoceramics, respectively. [3,4] These deformation strain rates are far too low for the potential application of plastic forming of complex shaped ceramic components at elevated temperatures.…”

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confidence: 99%

Consolidating and Deforming SiC Nanoceramics Via Dynamic Grain Sliding

et al. 2007

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The effort of grain refinement to achieve SiC nanoceramics has been driven by the expectation of the radical improvement of the mechanical performances and the superplasticity with decreasing grain size. [1,2] It requires the minimization of grain growth during sintering, i.e. to establish the optimized sintering condition where the grain-boundary migration is suppressed while the grain-boundary diffusion is stimulated. In principle, two approaches, namely solid-state sintering and liquid-phase sintering, have been adopted to densify SiC ceramics, with the major densification mechanism being identified as the grain-boundary diffusion enhanced by the segregated doping elements, e.g. boron, [3] and, respectively, by the liquid phase formed in grain-boundaries. [4] The densification is enhanced by the application of an external mechanical pressure, either uniaxial or isostatic. [3,5] It may be further enhanced by involving a disorder-order phase transformation, [6] by involving a suitable liquid that facilitates the solution-reprecipitation of the major phase, [7] or by allowing deformation to occur during densification, i.e. sinter forging. [5] So far, nanoceramics of SiC, as it is generally defined as ceramics consisting of grains less than 100 nm, have been prepared both by solid-state sintering and by liquid-phase sintering of nano-powders. [3][4][5][6]8] Their record superplastic deformation strain rate is in the order of 1 × 10 -5 /s above 1600°C and of 1 × 10 -4 /s at 1700°C for solid-state sintered and liquidphase sintered SiC nanoceramics, respectively. [3,4] These deformation strain rates are far too low for the potential application of plastic forming of complex shaped ceramic components at elevated temperatures. It appears that the achievable low deformation strain rate is yet an obstacle for densification, which yields the formation of a fraction of undesirable larger pores in the size range of 1-3 lm even under hot-pressing conditions. [5] In order to assure full densification, therefore, either time-consuming and/or more complicated sintering approaches, e.g. high pressure hot isostatic pressing, [3] pre-sintering plus sinter forging, [5] or two-step liquid-phase sintering, [8] have to be employed.A recent progress in achieving high deformation strain rate is to process materials by spark plasma sintering ® . Due to the very efficient heating and the influence of the electrical current/field on mass transport deformation strain rates in the order of 1 × [**] This work was partially supported by the Swedish Research Council through grant 621-2005-6290. We thank Prof. M. Nygren for valuable discussions. Fig. 1. Normalized shrinkage (a) and shrinkage rate (b) recorded during SPS processing of SiC nanoceramics. The applied heating rate is 100°C/min.

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“…heat exchanger, metal working parts, nozzles. [1][2][3][4][5][6] However, the low fracture toughness (around 2 MPa m 1=2 ) of SiC limits its more extensive usage. Titanium boride (TiB 2 ) is also an excellent engineering material with high electrical conductivity, thermal conductivity and hardness.…”

Section: Introductionmentioning

confidence: 99%

Preparation of TiB<SUB>2</SUB>–SiC Eutectic Composite by an Arc-Melted Method and Its Characterization

Goto

2005

Mater. Trans.

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TiB 2 -SiC system composites were prepared using TiB 2 and SiC powders as starting materials by an arc-melted method in Ar atmosphere. The TiB 2 -SiC system was binary eutectic. The eutectic composition was 40TiB 2 -60SiC (mol%) showing a labyrinth texture. The hardness of the eutectic composite was 27 to 30 GPa at the loads from 0.98 to 9.8 N. The electrical conductivity of the composites increased with increasing the content of TiB 2 . The electrical conductivity of the eutectic composite slightly decreased from 6.5 to 6:1 Â 10 5 Sm À1 with increasing temperature from 298 to 1200 K. The thermal conductivity of the composites increased with increasing the content of SiC. The thermal conductivity of the eutectic composite decreased from 70 to 45 WK À1 m À1 with increasing temperature.

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Consolidation of Nanostructured β‐SiC by Spark Plasma Sintering

Cited by 111 publications

References 32 publications

Influence of sintering temperature and pressure on crystallite size and lattice defect structure in nanocrystalline SiC

Influence of sintering temperature and pressure on crystallite size and lattice defect structure in nanocrystalline SiC

Consolidating and Deforming SiC Nanoceramics Via Dynamic Grain Sliding

Preparation of TiB<SUB>2</SUB>–SiC Eutectic Composite by an Arc-Melted Method and Its Characterization

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Consolidation of Nanostructured β‐SiC by Spark Plasma Sintering

Cited by 111 publications

References 32 publications

Influence of sintering temperature and pressure on crystallite size and lattice defect structure in nanocrystalline SiC

Influence of sintering temperature and pressure on crystallite size and lattice defect structure in nanocrystalline SiC

Consolidating and Deforming SiC Nanoceramics Via Dynamic Grain Sliding

Preparation of TiB<SUB>2</SUB>&ndash;SiC Eutectic Composite by an Arc-Melted Method and Its Characterization

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Preparation of TiB<SUB>2</SUB>–SiC Eutectic Composite by an Arc-Melted Method and Its Characterization