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Precursor-Derived Nanostructured SiC-Based Materials for MHD Electrode Applications
Program Manager: Dr. Jason Hissam
YiHsun Yang*, Fumio S. Ohuchi (PI)*, Amir H. Tavakoli**, and Rajendra K. Bordia(Co-PI)**
Department of Materials Science and Engineering*University of Washington
Box 352120, Seattle, WA 98195
** Clemson UniversityClemson, SC 29634
Grant No. DE-FE0023142April 21, 2016
• Withstand MHD environments:– Oxidation resistivity at high temperature– ion bombardment – plasma impingement– Mechanical thermal stability
• Conformal process• Low resistivity
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Technology advancements may bring newopportunities for legacy projects1974SiC
Reference: R-1656-ARPA Dec 1974 report by George Rudins)
ZrB2+SiC• Withstand MHD environments:– Oxidation resistivity at high temperature– ion bombardment – plasma impingement– Mechanical thermal stability
• Conformal process• Low resistivity
Hot plasma
To develop a novel class of SiC based ceramic composite materials with tailored compositions for channel applications in MHD generators.
Controlling and understanding the effect of the nature of the excess carbon and boron additive on the structural and electrical properties.
Role of excess carbon and boron Polymer based synthesis Structural information Electrical resistivity Work function from thermionic emission
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Long term goal
Today’s Focus
Lead: Prof. R. Bordia
Lead: Prof. F. Ohuchi
TASK 1: PROCESSING AND STABILITY OF NANOSTRUCTURED SI-C-X CERAMICSSub-Task 1.1: Effect of stoichiometry and temperature on the nanostructureSub-Task 1.2: Effect of temperature and stress on the stability of the nanostructure
TASK 2: MECHANICAL AND THERMAL PROPERTIES OF NANOSTRUCTURED SI-C-X CERAMICSSub-Task 2.1: Modulus, strength toughness, and thermal diffusivity Sub-Task 2.2: Compressive creep
TASK 3: ELECTRICAL PROPERTIES OF NANOSTRUCTURED SI-C-X CERAMICSSub-Task 3.1: Effect of C/Si ratio on room and elevated temperature electrical
conductivitySub-Task 3.2: Combinatorial selection of X and effect of X on room and elevated
temperature electrical conductivity
TASK 4: SURFACE ENGINEERING OF NANOSTRUCTURED SI-C-X CERAMICSSub-Task 4.1: Surface modification to enhance thermionic emissionsSub-Task 4.2: Changes of surface/sub-surface structure and chemistry by high
density plasma irradiation.
Sub-Task 4 3: Simulation of plasma interactions
Project Team Tasks
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4
Diversity of silicon based precursors• Liquid form polymer can be mixed homogeneously• Silicon / carbide ratio could be adjusted through precursors• Boron, nitrogen and oxygen can be easily incorporated• Relatively low process temperature
Easy of Process for Polymer DerivedCeramics (PDCs)
5P. Colombo, G. Mera, R. Riedel, and G. D. Sorarù, J. Am. Ceram. Soc. 93, 1805 (2010)
Process temperature:
Selection of polymer and processing• Precursor: SiC forming Allylhydridopolycarbosilane (Starfire® SMP-10)• Two processes has been developed
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Hot press
Polymer infiltration pyrolysis
SiC forming polymer(polycarbosilane SMP-10)
Carbon additive(divinylbenzene)
Sintering aid additive(decaborane)
Thermal cross-linking T = 400 oC
Cured polymer
Polymer power
grinding
SiC/C composite Pressed pellet
Pyrolysis T = 900 oC
Ultrafine powder
milling
SiC/C monolith
SiC/C monolith
Cold press
Hot pressing T = 2130 oC
Polymer infiltration Pyrolysis (PIP)
T = 1700 oC
Carbon additive:Improve electric conductivity
Boron additive:densification
Effects of different additives for polymer derived ceramics (PDCs)
Effect of dopants on the density of the hot-pressed samples:
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Sample ID Extra carbon Boron Bulk Density (g/cm3)
Relative Density (%)
nominal measured nominal measured0B0C 0 0 1.76 54.80B1C 1 0 2.8 87.2
1B2.9C 0 1.7(2.9)* 1 0.4 (0.8) 3.05 ± 0.09 95.9 ± 2.8*1B3.9C 1 2.2(3.9) 1 0.4 (0.8) 3.15 ± 0.03 99.4 ± 0.9*1B9.5C 5 5.6(9.5) 1 0.4 (0.8) 2.93 ± 0.06 94.2 ± 1.9*
wt%, mol% in parenthesis. Error is two standard deviation of the mean*Excess carbon from polymer precursor**Density is calculated based on the theoretical density of silicon carbide and graphite
Two phases matrices and elongated grains by Scanning Electron Microscopy (SEM)
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Polishedsurface
~ 1500 X
FracturedSurface~1000 X
1B2.9C 1B3.9C 1B9.5C
Boron wt%
Carb
on w
t%
9.5%
3.9%2.9%
Grain morphology and local crystallinity by Transmission electron microscopy (TEM)
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1B2.9C
1 μm
(fully crystalline) (Mostly crystalline) (Minor amorphous regions)
1B9.5C
1 μm
1 μm
1B9.5C
0.5 μm
1B2.9C
0.5 μm
1B9.5C
Boron wt%
Carb
on w
t%
9.5%
3.9%2.9%
The XRD analysis confirms the existence of 6H-SiC but is not enough for the complete identification of SiC polytypes.
Provides information for crystallized part; what if it is not fully crystallize? 10
Bulk crystallinity –X-Ray Diffraction
SiC1B9.5C
SiC1B3.9C
SiC1B2.9C
graphite
Solid state NMR provides bulk information for the chemical environment of the interested element.
Three characteristic chemical shift for 6H polytype.
Minor 3C polytype was found in some samples.
No silicon oxide peak. The NMR characterization
confirms the dominance of 6H-SiC for the three samples.
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Structural analysis by nuclear magnetic resonance (NMR) spectroscopy
SiC1B0CSiC1B1CSiC1B5C
6H-SiC
3C-SiC
1B2.9C
1B3.9C
1B9.5C
• We need to have the ability to measure the electrical conductivity / resistivity at elevated temperature.
• Standard commercial equipment does not lead us to over 700 oC – ZEN-3 Seebeck Coefficient / Electric Resistance
Measuring System from ULVAC Technologies, Inc.
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How is the ceramic going to behave above 1000 oC ?
We make one on our own!!!
Development of an “in-situ” measurement technique of dc-conductivity
Ma, F. Ph.D. Thesis 2015
Version 0 Version 1
Operation condition:
Version 0: Custom made box furnace, made with nichrome heating filament and aluminum cage with active water cooling. Capable up to 700 oC.
Version 1: Alumina plate, Moly screws and nuts, design for tube furnace. Capable up to 1000 oC.
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Development of an “in-situ” measurement technique of dc-conductivity Commercial 1700 C tube furnace Platinum lead, graphite contact
and alumina support Pseudo-four-point probe (Kelvin
probe) technique is applied. Control by LabVIEW
1700oCTube furnace
Ar Tank
Electrometer and current
source
PC for data acquisition
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Boron wt%
Carb
on w
t%
Effect of boron and carbon additive on electrical resistivity
0.1
1
10
100
1000
Res
istiv
ity (Ωc
m)
18001600140012001000800600400
Temp. (K)
1B2.9C (96%)
1B3.9C (99%)
1B9.5C (94%)0B1C(87%)
Fact: Carbon additive
lowers resistivity Boron additive helps
densification
Finding Boron additive tends
to increase resistivity unless huge amount
of extra carbon to compensate
9.5%
3.9%2.9%
Commercial SiC
50 s/m
Integrated HV chamber for surface modification and analysis
CMA
Retarding Grid
XPS
Sample apparatus
AES
TE
K source
Optical pyrometer
Integrated HV system:• Retarding grid spectroscopy to measure
thermionic emission (TE)• X-ray photoelectron spectroscopy (XPS)• Auger electron spectroscopy (AES)• K deposition for work function
engineering• R-type TC and optical pyrometer for
temperature measurement• Ion gun for surface cleaning
Capable of measuring: • Surface composition at elevated temp.• Total current and kinetic energy
distribution of thermionic emission.• Work function
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Ar
Ion gun
Surface self-regenerate under high temperature annealing
Ar
18
40
30
20
10
0
-10
dN(E
)/dE
, Int
ensi
ty (A
rb. U
nit)
500400300200100Electron Energy (eV)
PDC-SiC
Thin oxideThin oxideSurface organics
PDC-SiC
Self-regenerated graphite layer!!
Si LVV C KVV N KVV O KVV
As installedSputtered 30 mins
Sputtered 60 mins560 oC660 oC700 oC750 oC800 oC850 oC
5 Å10 Å
Auger electron spectroscopy for 1B9.5C
Ar
• Electric arcing or arc discharge: An electrical breakdown of gas.– It produces plasma discharge and often damage
the surface.
• Thermionic emission: an electron emission due to thermal activation.– A physical process that the amount of emitted
electron is determined by work function.
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A common failure reason for MHD channel electrodes - Arcing
What is work function and how do we measure it experimentally?
Energy
EF
Vacuum level
1.0 0.0 Fermi-Dirac Distribution
Population Density
E0
Φ
Energy
V0
Thermionic emission (TE) and Richardson-Dushman eq.
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A0-200V
-
-+
+
+20V
ComputerLabVIEWe
sample
Front view of electron grid
Workstation for data acquisition
-44
-42
-40
-38
-36
-34
-32
-30
-28
LN(I t
h/T2 ) (
A/K2 )
950x10-69008508007507006506001/Temp. (1/K)
'SiCSC_ab_2_LN(Ith/Tsq)'Φ = 4.00 eV
'SiCSC_ab3_1_LN(Ith/Tsq)'Φ = 4.02 eV
'SiCSC_ab_1_LN(Ith/Tsq)'Φ = 4.39 eV
-44
-42
-40
-38
-36
-34
-32
-30
-28
LN(I t
h/T2 ) (
A/K
2 )
950x10-69008508007507006506001/Temp. (1/K)
'SiC_D_3_LN(I/T2)'Φ = 4.14 eV
'SiC_D_1_LN(I/T2)'Φ = 5.52 eV / 4.36 eV (at HT zone)
'SiC_D_2_LN(I/T2)'Φ = 4.34 eV
1000x10-12
800
600
400
200
0
Em
issi
on C
urre
nt (A
)
140012001000800Temp. (
oC)
800x10-9
600
400
200
0
Em
issi
on C
urre
nt (A
)
140012001000800
Temp. (oC)
Work function converges for all samples after annealing
As installed
Annealed
Sputtered
4.39 eV
4.00 eV
4.02 eV
5.52 eV
4.34 eV
4.14 eV
As installed
Annealed
sputtered
Single crystal SiC
Work function:
Work function gradually converged to ~4 eV (graphite)
Work function:
SiC: 1B3.9C
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Future plan for further tailoring work functionIn-situ potassium deposition
C.-K. Choo, D. Suzawa, and K. Tanaka, Surf. Sci. 600, 1518 (2006)
• Potassium deposition on Si substrate
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• A new type of silicon carbide / carbon composite synthesized from polymer derived synthesis.
• Electrical resistivity of PDC SiC/C can be tailored by different carbon contain.
• The surface of SiC/C composite has unique property that grows graphite and can be self-regenerated.
• Work function measured through thermionic emission.
• High temperature mechanical properties is on going.• In-situ alkali metal deposition for work function
engineering is on going.• ICE plasma source has been constructed, ready to be
incorporated.
Summary of this project
Thank you!
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