Electrical properties of high resistivity 6H–SiC under high temperature/high field stress

Gradinaru, G.; Sudarshan, Tangali S.; Gradinaru, S.; Mitchell, William D.; Hobgood, H. McD.

doi:10.1063/1.118264

Cited by 17 publications

(5 citation statements)

References 10 publications

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“…This is hypothesized to be due to the slope of resistivity vs temperature curve for B 4 C being relatively constant 20 . In contrast to SiC, which tends to show a sudden drop in resistance 21 when the semiconductor reaches its intrinsic region at temperatures exceeding 1400 °C.…”

Section: Resultsmentioning

confidence: 94%

Ultrafast-Contactless Flash Sintering using Plasma Electrodes

Saunders¹,

Grasso²,

Reece³

2016

Sci Rep

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This paper presents a novel derivative of flash sintering, in which contactless flash sintering (CFS) is achieved using plasma electrodes. In this setup, electrical contact with the sample to be sintered is made by two arc plasma electrodes, one on either side, allowing current to pass through the sample. This opens up the possibility of continuous throughput flash sintering. Preheating, a usual precondition for flash sintering, is provided by the arc electrodes which heat the sample to 1400 °C. The best results were produced with pre-compacted samples (bars 1.8 mm thick) of pure B4C (discharge time 2s, current 4A) and SiC:B4C 50 wt% (3s at 6A), which were fully consolidated under a heating rate approaching 20000 °C/min. For the composite a cylindrical volume of 14 mm3 was sintered to full density with limited grain growth.

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Section: Resultsmentioning

confidence: 94%

Ultrafast-Contactless Flash Sintering using Plasma Electrodes

Saunders¹,

Grasso²,

Reece³

2016

Sci Rep

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“…That experiment was interesting; however repeatable results were unobtainable. Future work involving doping silicon carbide with vanadium to change the dielectric loss would be useful toward developing a microwave thermal thruster, and the current laboratory setup is suitable for such an endeavor [7]. …”

Section: Discussionmentioning

confidence: 99%

Axial Temperature Behavior of a Heat Exchanger Tube for Microwave Thermal Rockets

Bruccoleri

Parkin

Barmatz

2007

Journal of Propulsion and Power

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Nomenclature A = channel cross sectional area c p T = specific heat at constant pressure D = channel diameter HT = convective heat transfer coefficient kT = fluid thermal conductivity l = channel length _ m = mass flow rate Nu = Nusselt number P = inner channel perimeter Pr = Prandtl number q 00 convection = convective heat flux q 00 radiation = radiation heat flux q tube = heat rate Re = Reynolds number T m = mean fluid temperature T w = wall temperature T 1 = ambient temperature u m = mean fluid velocity " = emissivity T = viscosity = density = Stephan-Boltzmann constant

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“…Silicon carbide (SiC) exhibits good resistance to corrosive environments, is stable at high temperatures, and has excellent mechanical properties, for example, high hardness. These properties make SiC a promising materials for such applications as high‐temperature coatings and microelectromechanical system .…”

Section: Background and Motivationmentioning

confidence: 99%

Plasticity‐Controlled Friction and Wear in Nanocrystalline SiC

2014

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Wear resistance of ceramics can be improved by suppressing fracture, which can be accomplished either by decreasing the grain size or by reducing the size of the deformation zone. We have combined these two strategies with the goal of understanding the atomistic mechanisms underlying the plasticity-controlled friction and wear in nanocrystalline (nc) silicon carbide (SiC). We have performed molecular dynamics simulations of nanoscale wear on nc-SiC with 5 nm grain diameter with a nanoscale cutting tool. We find that grain-boundary (GB) sliding is the primary deformation mechanism during wear and that it is accommodated by heterogeneous nucleation of partial dislocations, formation of voids at the triple junctions, and grain pull-out. We estimate the stresses required for heterogeneous nucleation of partial dislocations at triple junctions and shear strength of GBs. Pile up in nc-SiC consists of grains that were pulled out during deformation. We compare the wear response of nc-SiC to single-crystal (sc) SiC and show that scratch hardness of nc-SiC is lower than that of sc-SiC. Our results demonstrate that the higher scratch hardness in sc-SiC originates from nucleation and motion of dislocations, whereas nc-SiC is more pliable due to additional mechanism of deformation via GB sliding.

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Electrical properties of high resistivity 6H–SiC under high temperature/high field stress

Cited by 17 publications

References 10 publications

Ultrafast-Contactless Flash Sintering using Plasma Electrodes

Ultrafast-Contactless Flash Sintering using Plasma Electrodes

Axial Temperature Behavior of a Heat Exchanger Tube for Microwave Thermal Rockets

Plasticity‐Controlled Friction and Wear in Nanocrystalline SiC

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