Abstract
Plasma pressure compaction (P2C) is a novel sintering technique that enables the consolidation of silicon carbide with a nanoscale microstructure at a relatively low temperature. To achieve a high final density with optimized mechanical properties, the effects of various sintering factors pertaining to the temperature-time profile and pressure were characterized. This paper reports a design of experiment approach used to optimize the processing for a 100 nm SiC powder focused on four sintering factors: temperature, time, pressure, and heating rate. Response variables included the density and mechanical properties. A L9 orthogonal array approach that includes the signal-to-noise (S/N) ratio and analysis of variance (ANOVA) was employed to optimize the processing factors. All of the sintering factors have significant effect on the density and mechanical properties. A final density of 98.1% was achieved with a temperature of 1600?C, hold time of 30 min, pressure of 50 MPa, and heating rate of 100?C/min. The hardness reached 18.4 GPa with a fracture toughness of 4.6 MPa?m, and these are comparable to reports from prior studies using higher consolidation temperatures.
Highlights
Silicon carbide (SiC) is used for applications in severe high temperature and high stress conditions
This study identifies the optimal processing conditions for sintering of nanocrystalline SiC using the P2C system
Tab.III The output characteristics based on the L9 orthogonal array
Summary
Silicon carbide (SiC) is used for applications in severe high temperature and high stress conditions. Sintering additive contents are reduced with smaller particle sizes This results in enhancement of properties such as increased fracture toughness and higher strength at room temperature as well as high temperature, tailorable electrical resistivity, enhanced wear resistance, and increased ductility and greater superplasticity at high temperatures [4]. Sintering depends on the powder characteristics, as well as the additives and process parameters such as sintering temperature, time, pressure, and heating rate, including the potential for liquid phase sintering. This complexity further increases with the P2C technique since it brings in new attributes from the electrical discharge specifics. The signal-to-noise (S/N) ratio and the analysis of variance (ANOVA) techniques are used to calculate the contributions of each of the processing parameters to the output characteristics
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