sayir - aerospace materials for extreme environments - spring review 2013
DESCRIPTION
Dr. Ali Sayir presents an overview of his program, Aerospace Materials for Extreme Environments, at the AFOSR 2013 Spring Review. At this review, Program Officers from AFOSR Technical Divisions will present briefings that highlight basic research programs beneficial to the Air Force.TRANSCRIPT
1 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution 15 February 2013
Integrity Service Excellence
Dr. Ali Sayir
Program Officer
AFOSR/RTD
Air Force Research Laboratory
AEROSPACE MATERIALS
FOR EXTREME
ENVIRONMENTS
Date: 7 March 2013
2 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
2013 AFOSR SPRING REVIEW
NAME: AEROSPACE MATERIALS FOR EXTREME ENVIRONMENTS
BRIEF DESCRIPTION OF PORTFOLIO:
To provide the fundamental knowledge required to enable revolutionary
advances in future Air Force technologies through the discovery and
characterization of materials that can withstand extreme environments.
LIST SUB-AREAS IN PORTFOLIO:
• Theoretical and computational tools that aid in the discovery of new materials. • Ceramics
• Metals
• Hybrids (including composites)
• Mathematics to quantify the microstructure to Predictive materials Science
• Physics and chemistry of materials in highly stressed environments
• Experimental and computational tools to address the complexity of combined
external fields at extreme environments.
3 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
OUTLINE
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environment
III. Challenges, Motivations and New initiatives.
4 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
“The Dream:” Computational Material Design
Pick a set of structures
& compositions
Calculate their
properties
Improve
structure/composition
Experimental
fabrication & testing
“Optimal?” No
Yes
Computer
Lab or Fab
W. Windl (OSU), K. Flores (WASHINGTON U. ), D. Hoffmann (CALTECH), E. Marquis (U. MICHIGAN
5 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Ab-Initio Calculations
Ab Initio Code
Hy = Ey
Input:
H O H
Output:
H
O
H
Structure,
Energy
~2.5 Å
core
hole
effect
Theor.
(scaled)
Expt.
~5 Å
Theor.
Expt.
(scaled)
(a)
(b)
(c)
(d)
(e)
(f)
(g)
(h)
Band structure
EELS spectra
Kinetic parameters
Thermal properties
Mechanical prop’s
W. Windl (OSU), K. Flores (WASHINGTON U. ), D. Hoffmann (CALTECH), E. Marquis (U. MICHIGAN
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Calculating Glass-Forming Ability
Tm
Tg
Good packing
density
No crystalline
symmetry (5-fold)
Stabilize liquid;
don’t lead to crystal nuclei Frank, F. C. (1952).
Liquid
Crystal
Crystallization inhibitors:
1. Driving Force: Icosahedra
2. Kinetics: Viscosity (fragility)
Direct Measurement:
Critical Cooling Rate
–Not computationally feasible
–Real time: 1 ms
–20 CPUs: 200 Years
critical
cooling rate
W. Windl (OSU), K. Flores (WASHINGTON U. ), D. Hoffmann (CALTECH), E. Marquis (U. MICHIGAN
7 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Interatomic Potentials
0.0%
2.0%
4.0%
6.0%
8.0%
35.0 45.0 55.0
Zr [at%]
Icosahedron Fraction
• Chosen Method: Green-Kubo
=
t
Bt
dstPstPTk
V
0
00 )()(lim
Zr
Al
Ni
Glassy &
Ductile!
atomistics.osu.edu
6.8254.66 ZrNiAl
Glass
Formable
regions
Ward, Agrawal,
Flores, Windl
(to be published)
W. Windl (OSU), K. Flores (WASHINGTON U. ), D. Hoffmann (CALTECH), E. Marquis (U. MICHIGAN
8 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Metallic glass electrode- A closer
look
A. Taylor (YALE)
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OUTLINE
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environment
III. Challenges, Motivations and New initiatives.
10 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Direct MD prediction compared to fracture and
dislocation nucleation models for SiC
2/15/2013 10
Fracture on 111
shuffle plane Dislocation on
111glide plane
211
111
Fracturing
After fracture
211
111
Devanathan potential
211
111
211
111
dislocation nucleating
After dislocation nucleates
Erhart potential
Devanathan potential activation energy vs
temperature
0
0.2
0.4
0.6
0.8
1
1.2
1.4
0 200 400 600 800
Temperature (K)
Ene
rgy
rele
ase
rate
(E
/Gb)
111 surface energy
Erhart potential activation energy vs
temperature
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 200 400 600 800
Temperature (K)
Ene
rgy
rele
ase
rate
(E
/Gb)
111 surface energy
• Activation energy predicted
by the continuum model
• Elastic constants(T) + surface
energies(T) + unstable
stacking fault energies(T) +
3 0
3
ln( )D B
DBI
I
Q k TN
dQk TK
dK
=
D. Warner (CORNELL U.)
11 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Orientation Relationship of TaC and Ta4C3 phase
(1,-1,1)
70o
<110>
TaC
<110>
(1,1,-1)
<111>
500 nm
70o
TaC FCC-like structure yields FOUR {111} variants
– leads to equivalent precipitation habit planes for
Ta4C3 -criss-cross pattern morphology of laths
{111} planes Loss of C on
{111} plane to
yield Ta4C3
G. Thompson (U. ALABAMA)
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1 1
2
2
5μm
1
5μ
m
1
4μm
2
2μm
2
5μm
2 • Deviation from linearity
• Pop-in or displacement bursts, buckling, cracking
• Max CRSS on {111} planes
• Plastic flow due to formation of slip bands
• Shearing and cracking rather than catastrophic fracture specially
in 6μm pillars
Unsolved Problem: Scale Effect ZrC(001)
S. Kodambaka (UCLA)
13 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
OUTLINE
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environment
III. Challenges, Motivations and New initiatives.
14 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
www.nhsc-ms.org
National Hypersonic Science Center
• Highly integrated research program: graduate students & post docs
• 35 journal publications; 23 plenary/keynote presentations at international conferences
(including Mueller award lecture at ICACC'12, 4 lectures at 2012 Ceramics Gordon
Conference); 12 conference proceedings; 25 other conference papers
• Active collaborations with 10 universities.
• Sharing of data & modeling with AFRL, Army, NASA, Rolls Royce
• Organized International Summer School on Materials for Hypersonics, UCSB, Aug.
2011. Organized International workshop on high-temperature ceramic composites,
Boulder CO June 12-15 2012; www.engineceramics.org
D. Marshall, B. Cox (TELEDYNE), F. Zok (UC SB), B. Fahrenholtz (MST), P. Kroll (UT AUSTIN), Q. YANG (U. MIAMI), R. RITCHIE (UC BERKELEY)
15 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
3-D Microstructural Characterization and
Geometry Generator
Compound visualization of statistical parameters
5mm
Compound visualization of statistical parameters
5mm
Tow cross
sectional
area
3-D image of C-SiC
composite
computational mesh
from geometric model analogue of Markov
chain method for tow
axis coordinates
stochastic irregular
elliptical cylinder for
each tow
problem: interpenetration
solution: enforce known
topology of textile
Statistical description of geometry Tow paths
Cross-sectional areas
Orientation of cross section
Deviations from mean
Correlation lengths
create replicas of textile
reinforcement with same
statistics as those measured
D. Marshall, B. Cox (TELEDYNE), F. Zok (UC SB), Q. YANG (U. MIAMI), R. RITCHIE (UC BERKELEY)
16 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution 127 N, 25 oC
In-situ testing SiCf/SiCm at 25˚C
Load Extension Curve
(Single tow 1750˚C)
0
20
40
60
80
100
120
140
160
0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35Extension (mm)
Load
(N
)
8 8 octopoleoctopole 1000W1000W
IR lamps IR lamps
XX--raysrays
dogdog--bonebone
sample sample
water water
coolingcooling
and sample and sample
mount accessmount access
360 deg 360 deg
thin windowthin window
0.25 mm Al 0.25 mm Al
Lamp
Lamp
Lamp
Lamp
Lamp
to load cell and water cooling to load cell and water cooling
guidewayguideway
motor andmotor and
gearboxgearbox
X-rays
load cell load cell
furnace furnace
section section
with with
active active
cooling cooling
OctopoleOctopole IR lamp IR lamp
arrangement arrangement
water water
coolingcooling
LBNL design : LBNL design : J.NasiatkaJ.Nasiatka, , A.MacDowellA.MacDowell
8 8 octopoleoctopole 1000W1000W
IR lamps IR lamps
XX--raysrays
dogdog--bonebone
sample sample
water water
coolingcooling
and sample and sample
mount accessmount access
360 deg 360 deg
thin windowthin window
0.25 mm Al 0.25 mm Al
Lamp
Lamp
Lamp
Lamp
Lamp
to load cell and water cooling to load cell and water cooling
guidewayguideway
motor andmotor and
gearboxgearbox
X-rays
load cell load cell
furnace furnace
section section
with with
active active
cooling cooling
OctopoleOctopole IR lamp IR lamp
arrangement arrangement
water water
coolingcooling
LBNL design : LBNL design : J.NasiatkaJ.Nasiatka, , A.MacDowellA.MacDowell
In-situ testing SiCf/SiCm at 1750˚C
In-Situ 3D Tomography at 1750 C
R. Ritchie (UC BERKELEY)
Nature of
Materials 2013
17 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Comparison of Simulation and
in-situ Tomography
In situ tomography 1750oC
D. Marshall, B. Cox (TELEDYNE), F. Zok (UCSB), Q. Yang (U. MIAMI), R. Ritchie (UC BERKELEY)
18 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
OUTLINE
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environment
III. Challenges, Motivations and New initiatives.
19 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Materials Far from Equilibrium:
Micro-Architectured Surfaces N. Ghoniem / UCLA
Plasma Erosion & Modeling (Wirz - UCLA).
Plasma Source Development (Goebel – JPL/UCLA)
Secondary Electron Emission & Plasma Modeling (Raitses,
Kaganovich - PPPL).
Materials Characterization (Thompson - UA).
High Heat Flux Testing (Ghoniem - UCLA).
Manufacturing of Micro-architectured Materials (Williams -
ULTRAMET).
Multiscale Modeling of Material Damage (Ghoniem - UCLA).
Hole formation
[1994(MJ/m2),
0.2 (MW/m2)]
20 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
[360 (MJ/m2),0.2 (MW/m2)] Hole formation
[641(MJ/m2),0.2 (MW/m2)] Fine hole formation
[1441(MJ/m2),0.2 (MW/m2)] Hole formation
[128(MJ/m2),0.02 (MW/m2)] No damage
[721(MJ/m2),0.4 (MW/m2)] Limited damage
Hole formation
Damage for Heat flux < 1 MW/m2 N. Ghoniem (UCLA), Y. Raitses and I. Kaganovich (PRINCETON),
G. Thompson (U. ALABAMA), B. Williams (ULTRAMET)
[1994(MJ/m2),0.2 (MW/m2)]
21 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Atomistic Simulations of Surface Defects in W
under Plasma Bombardment
Hopping of the adatom is the dominant
mechanism on (110) surface. The formation and
the movement of surface crowdions contributes
mostly on (001) surface. Exchange mechanism is
also important on (001) surface, biaxial strain can
manipulate the relative contribution of Path-Ex
and Path-Crow.
(001) (110) r(r) of surface crowdion indicates the high
mobility and strong anistropy of its movement.
MD simulation indicates that the bombardment
of a Xe atom induces ballistic diffusion of W
atoms (W1 in the graph) and causes the
formation and evolution of crowdions near the
surface. Snapshots of the bombardment of a Xe atom (KE =
100 eV) on W(001) surface at T = 200 K.
N. Ghoniem (UCLA)
22 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Vacancy Production in Surface Layers Leads to
Surface Instabilities
Jerome Paret. Long-time dynamics of the three-dimensional biaxial
grinfeld instability. Physical Review E, 72:01105–1–5, 2005.
D. Walgraef, N.M. Ghoniem, and
J. Lauzeral. Deformation patterns
in thin films under uniform laser
irradiation. Phys.Rev., B
56:15361–15377, 1997.
N. Ghoniem (UCLA)
23 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
OUTLINE
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environment
III. Challenges, Motivations and New initiatives.
24 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Spatially resolved
measurement location
N + N + [s] → [s] + N2
Flight environment to ground
facility testing comparison
Approach: Compare surface-
catalyzed reaction efficiencies for
flexible and rigid materials with same
elemental composition by measuring
relative atom density and
temperature gradients above
material samples in the 30 kW ICP
Torch Facility using laser induced
fluorescence
Surface Catalysis Testing in a 30kW ICP
Torch Facility D. Fletcher (U. VERMONT), J. Marshall (SRI), M. Akinc (ISU), J. Prepezko (U. Wisconsin)
25 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
•Relative N atom concentration measurements for quartz and monolithic -SiC
•Increasing concentration toward wall indicates low surface catalyzed reaction efficiency
•From the nN plot, it can be seen that -SiC (Tw = 1300 K) is of comparable catalycity to quartz (Tw <
1000 K)
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5
0
1000
2000
3000
4000
5000
6000
7000
Quartz [20120404]
SiC Puck [20120321]
Distance Above Surface [mm]
=1
Norm
aliz
ed n
N [
a.u.]
=0
Tem
per
ature
[K
]
Distance Above Surface [mm]
=0
Surface Catalytic Effect of SiC Testing in a
30kW ICP Torch Facility D. Fletcher (U. VERMONT), J. Marshall (SRI), M. Akinc (ISU), J. Prepezko (U. Wisconsin)
26 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
OUTLINE
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environment
III. Challenges, Motivations and New initiatives.
27 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
Si
SiO2
SrTiO3
TiO2
Protective Ir
Interfacial dielectric response Electron Energy Loss Spectroscopy
2012 BRI: 2D-Materials for Extreme Environments
2013 BRI: Charge Transfer at the Interface
A. Demkov, unpublished work
Demkov 2010 Inoue 2009 Heidger 2012
• Demkov: Diffuse Interface
• Inoue: Stoichimetyry of Hf1-xO2-x
• Heidger: Termination
D. A. Muller et al., Nature Material 8, 263 (2009)
28 DISTRIBUTION STATEMENT A – Unclassified, Unlimited Distribution
SUMMARY
I. Predictive Materials Science Bulk Metallic Glasses
Carbides (SiC, TaC, Ta4C)
Textile Based Hybrid Composite (NHSC)
2012 MURI: Mosaic of Structure (CMU): Descriptor Challenge (wt. Dr. Fahroo)
2012 MURI: Atomic Scale Interface (LEHIGH) / (Dr. Shifler / ONR)
2013 MURI: Peridynamics (wt. Drs. Stargel & Fahroo)
II. Materials Far from Equilibrium Micro-Architectured Surfaces
Surface Catalysis at Extreme Environments
2013 BRI: Layered Structured Materials (2D E-Gas)
III. Challenges, Motivations and New initiatives
2012 MURI: Template-Directed Directionally Solidified Eutectic Metamaterials
2013 MURI: Magneto-Electric Energy Conversion Materials and Terahertz
Emission in Unbiased Dielectrics (wt. Dr. Luginsland)
2013 BRI: Metal Dielectric Interface: Charge Transfer in Heterogeneous
Media under Extreme Environments (wt. Dr. Luginsland)