Post on 04-Oct-2020
The Science and Technology of High Temperature Hf-SiCN(O) Polymer Derived Ceramics
Rishi Raj Ph.D. Students: Kalvis Terauds Ilya Lisenker
August 06, 2013
AFOSR-NASA FA9550-09-1-0477
Active Collaborators: D. B. Marshall (Teledyne): CMCs P. Kroll (UT Arlington): Molecular Modeling J. Marschall (SRI, Int.): Plasma Testing Y. Shinoda (Tokyo Institute of Technology): Oxide/non-Oxide Nanocomposites. Emerging Collaborations: *Prof. Steven George (Chemistry, CU) : MLD Prof. Chuck Winter (Chemistry, Wayne State): Synthesis
*A. Abdulagatov, K. Terauds, J. Travis, A. Cavanagh, R. Raj, S. George, "Pyrolysis of Titanicone Molecular Layer Deposition Films as Precursors for Conducting TiO2-Carbon Composite Films", J. Phys. Chem., accepted, in press.
Highlights: (i) Oxidation and phase transformation
in materials made with HfSiCNO (polymer derived) and HfO2.
(ii) Performance of Fiber Preforms: infiltrated with above.
(iii) Focus on SiC/HfSiCNO Interface: interfacial energy and bubble nucleation.
Ab-Initio!
molar C 13
Polymer-Derived oxide/non-oxide Ceramics
Raman
Si1-xHfx
Polymer-Derived Matrix: Impede Oxidation
Carbon Fiber Tows
HfSiCNO Matrix (infiltration)
Processing Defects
• Active Oxidation (recession) • CO Bubbles
Nanophase HfSiCNO-HfO2
(Terauds, Marshall and Raj) (Lisenkar, Terauds, and Raj)
Hf/Si →∞0←
Overgrowth
Matrix of the
Powder Particle
(a) (b)
Hf/Si = 0.22
Oxidized for 50h at 1500oC in air
HfSiCNO Hf/Si = 0-38%
• Molecular structure • Solubility, Precipitation and Coarsening • Oxidation Behavior
Processing
Alkoxide (Hf t-butoxide)
Polymer (Ceraset)
Hf, O, C, H Si, N, C, H
Crosslink at 300°C
Pyrolysis at 1000°C
Mix precursors
Oxidize 1400°C - 1600°C
Structure of HfSiCN
Hypothesis: Hf substitutes for Si; (same valency, similar strength of Hf-N, Hf-C and Hf-O bonds)
Bond-Energy Calculations (manual)
Bond energies are relative to Si-C and Si-N
Hf N
N
C
C
��
��
��
�
���
���
Enth
alpy
(kJ.
molï�
)
MO4 MC1O3 MC2O2 MC3O1 MC4
Hf Zr
Ti
V
Al
NbTa
Oxygen containing mixed bonds
favorable
unfavorable
Hf
Hf-Si-C-N-O: S22 model Hf-coordination
Hf(1) Hf(2) Hf(4) Hf(3)
Hf(5) Hf(6) Hf(7) Peter Kroll
N C
O
Hf
29 atoms Si 7 atoms Hf
Infer that Hf substitutes for Si in the Amorphous Structure
Solubility Limit: (Hf/Si) < 0.22
Samples pyrolyzed at 1000oC in Ar
HfSiCNO Powder Oxidation (S08)
HfSiCNO Powder Oxidation (S08) 1500oC 50h Air
0
10
20
1 10 25 50
Wei
ght F
ract
ion
(%)
Oxidation Time (h)5
SiO2(cristobalite)
HfO2(M)
HfO2(T)
HfSiO4
1500°C, AirHfSiCNO
Quantitative X-ray diffraction with Nb standard
Oxidation of HfSiCNO
Key Results: • HfO2 precipitates from solution. • HfO2 reacts with silica in the oxidation scale to form HfSiO4 (hafnon). • The evolution of a unique microstructure during oxidation.
What is the coarsening rate of HfO2 precipitates?
materials science model
ab-initio experiment
A New Paradigm Goal: Predict Oswald Ripening
Unknown: transport kinetics =diffusivity* x solubility
calculate heat of solution
predictive model w/o adjustable parameters
+
*Diffusivity is related to viscosity via Stokes Einstein
valid
ate
with
on
e or
two
expe
rimen
ts
(Raj) (Kroll)
manuscript to be submitted
S Y N E R G Y PREDICT PERFORMANCE
DISCOVER NEW MATERIALS
Overgrowth
Matrix of thePowder Particle
bright spots are precipitates of hafnia
(a) (b)
(c) (d)
1 m
5 m
∆Hmix ≈ 1.2 eV
Peter Kroll
x HfO2= exp(−1.2eV
RT)
•Relate diffusivity to the viscosity through Stokes Einstein •Calculate the rate of coarsening of hafnia precipitates. •Predict oxidation protection
Nanophase HfSiCNO-HfO2
(Terauds, Marshall and Raj) (Lisenkar, Terauds, and Raj)
300 nm
10% SiCN
As-Pyrolyzed
Sintered in argon (1450°C)
Sintered in air (1450°C)
HfO2-10%SiCN
Raman Spectra confirms the presence of PDC at Grain Boundaries.
0 200 400 600 800 1000 1200
Intensity, a.u.
Wavenumber, cm-‐1
Raman Spectrum, HfO2 -‐ 10%PDC, 30 hours at temperature
♦ -‐ HfO2♦
♦
♦♦♦ ♦♦
♦♦
♦
♦♦♦
♦♦ ∇ -‐ HfSiO4
∇∇ ∇
∇∇
♦
As Sintered
1,300°C
1,400°C
1,500°C
1,600°C∇
in air
RAMAN
0100200300400500600
1,300 °C 1,400 °C 1,500 °C 1,600 °C
Flexural Stren
gth, M
pa
Oxidation Temperature, °C
Hafnia / 10% PDC Flexural Strength3 point bending
0 hrs
10 hrs
30 hrs
Jochen Marschall SRI, International
Oxidation in the Plasmatron
Atomic Oxygen
YS Samples
YS3 1200oC
Off +0.55mg
YS4 1200oC
On +2.74 mg
Dual Phase (HfO2 – SiC) Composites
Yutaka Shinoda (Tokyo Institute of Technology) & David Marshall
Oxidation at 1600oC in air: Minimal effect on Strength
Thermal Conductivity
Values are much higher than predicted by models for isolated dispersions: SiC have an interconnected structure.
KC
Km
= 1(1− f )3
Every, Tzou, Raj, 1992
X-ray patterns of as-sintered and oxidized HfO2-30vol%SiC ceramics
HfSiO4
HfO2 (monoclinic)SiO2 (crystobalite)
2 [º ]
Inte
nsity
[cps
]
5. X-ray di!raction of the oxidation scale formed at di!erent tempera-tures. Note the presence of HfSiO4, and the absence of cristobalite at the high temperatures.
5 µm
127
µm
100 µm
1600oC, 10h, air
hafium silicate hafium oxide
0
20
40
80
100
120
140
1200 1300 1400 1500 1600
Thic
kkness o
f O
xid
e S
cale
, µm
Oxidation Temperature [ºC]
60
unoxidized HfO2-SiC
HfO2 + SiC + 32O2 = HfSiO4 +CO ↑
• Oxide scale is a matrix of HfSiO4 with a dispersion of HfO2. • 13.8% volume expansion ensures a robust oxidation scale. • The scale has good mechanical properties. • CO is partly sequestered within bubbles, and partly diffuses out to the atmosphere (based upon pressure calculation).
Oxidation behavior of Infiltrated Fiber Preforms
Polymer Derived SiCN
Polymer Derived HfO2or HfO2 powder
HfO2/SiCN
SiCN vol% = 5-40%
HfSiCNO
Hf/Si = 0-40%
Unoxidized
Oxide Scale
Epoxy
1 µm 1500oC, 50h, air
Polymer Derived SiCN
Polymer Derived HfO2or HfO2 powder
HfO2/SiCN
SiCN vol% = 5-40%
HfSiCNO
Hf/Si = 0-40%
Unoxidized
Oxide Scale
Epoxy
1 µm 1500oC, 50h, air
Unoxidized material
Oxide layer (10 um)
Epoxy
Powder oxidation, 1500°C, 1000 hours
Please note the absence of CO bubbles in HfSiCNO (because they are amorphous)
Hf/Si = 0.38
Oxidation behavior of Infiltrated Fiber Preforms
Polymer Derived SiCN
Polymer Derived HfO2or HfO2 powder
HfO2/SiCN
SiCN vol% = 5-40%
HfSiCNO
Hf/Si = 0-40%
Epoxy
•Hf/Si of 0.38 is a promising matrix*. •New processing approach to counter shrinkage.
*(i) HfSiO4 will prevent recession in streaming-humid atmosphere. (ii) CO bubble nucleation is impeded.
Optical micrograph of as-infiltrated sample
HfO2/SiCN infiltration
Oxidation behavior of Infiltrated Fiber Preforms
Polymer Derived SiCN
Polymer Derived HfO2or HfO2 powder
HfO2/SiCN
SiCN vol% = 5-40%
HfSiCNO
Hf/Si = 0-40%
Epoxy
•Hf/Si of 0.38 is a promising matrix*. •New processing approach to counter shrinkage.
*(i) HfSiO4 will prevent recession in streaming-humid atmosphere. (ii) CO bubble nucleation is impeded.
Optical micrograph of as-infiltrated sample
HfO2/SiCN infiltration
Oxidation Expts and Observations
1500oC, water, 5-30h
Three Reactions: free surface of the matrix matrix-CVI (SiC) interface (c) inside CVI (SiC) free surface from C-fiber burnout
(a) (b)
(a)
(b)
CO Bubble formation (bloating) SiC + 3
2O2 → SiO2 +CO ↑
Streaming H2O, 1400°C, 25hrs
1600oC, 100hrs, air (dry O2)
bubble
Schiroky et al. 1986
SiC Single Crystal
HfO2 top-coat
oxidized SiCN(O)interlayer
1500 oC 100h, ambient air
Oxidation Expts and Observations
1500oC, water, 5-30h
free surface of the matrix matrix-CVI (SiC) interface
(a)
(b)
(b)
(a)
CVI SiC
Epoxy
HfO2/SiCN Infiltrated Layer
At the Free Surface
Oxidation as a function of depth from outer surface
(a)
At outer surface At 300 μm depth
HfSiO4 and HfO2 HfSiO4, HfO2, and SiO2 SiCN and HfO2
Streaming H2O, 1500°C, 30 hours
Epoxy
SiO2 HfO2 (light)
HfSiO4 (dark)
At 100 μm depth
Streaming H2O, 1500°C, 30 hours
HfO2 (light) and HfSiO4 (dark)
bubble pockets are confined to within the matrix
(These results are comparable to those from HfO2-SiC Dual-Phase Nanocomposites.)
1500oC, water, 30h
(b) CVI SiC
Epoxy
HfO2/SiCN Infiltration
At the Matrix / CVI-SiC Interface
CVI SiC
w/o SiO2
SiO2 on SiC exposed by C-burnout
HfO2-SiCN matrix
Streaming H2O, 1500°C, 5 hours Flow direction
some ballooning: bubbles at surfaces of CVI-SiC exposed by C-fiber burnout
Oxidized 1500°C, 100 hours, air
Recession at the unprotected leading edge
Streaming H2O, 1500°C, 30 hours
Flow direction
recession
SiC HfSiCNO/HfO2
Steam Steam
Bubbles Bloating? within the matrix (w/o bloating)
Recession Yes No
SiC HfSiCNO/HfO2
Air Air
Bubbles Yes (bloating)
within the matrix (w/o bloating)
Recession No No
Temp :1400 − 2000oCpO2 = 10
–6 −1 atmIn steam SiC suffers active oxidation
Failure Mechanisms: 1. Bubbles, 2. Active Oxidation (Recession)
Bubble Nucleation and Growth
• Model (What is the “DNA” of the phenomenon?) • Focus in SiC-Silica Interface • ab-initio materials discovery chemical synthesis experiment repeat
Phenomena have their genesis in atoms and molecules!
the DNA
1600oC 100h, ambient air
The Mechanism: •SiC-oxide interfacial energy determines the nucleation barrier. •Viscosity of silica significantly affects incubation time.
The Concept: Hf doping into silica may affect interfacial energy. Viscosity?
The Steps: ab-initio for material discovery (Peter Kroll) followed by synthesis (Steve George/Chuck Winter), followed by experiment…..
Influence of water on interfacial energies and viscosity?
Bubble Nucleation and Growth: Analysis and Remediation
b-SiC a-SiO2 a-SiO2
Surface energy, g = [E(model)-E(b-SiC)+E(a-SiO2)]/Area = 1.4 ± 0.2 J/m2
“natural” cavities, due to surface bridges O on SiC
Interface structure b-SiC(100)||a-SiO2
SiC-SiO2 interfaces
• how much open void space accumulates towards the interface? • impact of HfO2 on surface structure (preferred segregation?) • pCO higher at interface – impact on transport mechanism of CO?
Tentative but Significant Observations: (i) HfSiCNO matrix can prevent recession in streaming wet
environments.
(ii) The HfSiCNO matrix shifts bubble formation (nucleation) from the SiC interface to within the matrix, where the bubbles can be accommodated without bloating.
The degree of recession and the change in the bubble formation behavior remain to be rigorously substantiated.
SUMMARY
Plan for the coming year: •Quantify bubble nucleation and active oxidation (recession) mechanisms. •Develop process for HfSiCNO infiltration of fiber preforms. •Ab-initio of interfaces and viscosity, materials discovery and chemical synthesis to test viability.
Publish three to five additional papers.
in press
BUILDING FOR THE FUTURE
• One-week long summer workshops in Boulder attended by young and experienced researchers, industry, universities and international institutes: www.engineceramic.org. 1st Workshop - 2012 2nd Workshop – 2014 • (unsuccessful) DMREF proposal to NSF (FY 2013) involving, Wayne State (Chuck Winters), Case Western (Frank Ernst + Jennifer Carter), Akron (Greg Morscher), Cornell (Leigh Phoenix), Dave Marshall and General Electric.