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2 Managed by UT-Battellefor the U.S. Department of Energy
Project Overview
• Project is ongoing but re-focused each year to address current DOE and industry needs
– FY10 focus: LNT dopant study – FY09 focus: Component LNT study– FY08 focus: Desulfation of sectioned
LNTs and sulfur coverage on Pt
• Fuel penalty– Regeneration & desulfation of emission
controls require extra fuel consumption• Durability and Cost
– Large built-in PGM margin required to meet durability requirements/emissions standards
Timeline
Budget
Barriers
• Funding received– FY09: $100K– FY10: $200K
• $150K allocated to date• Anticipate similar funding for FY11
Partners• Collaborators and their roles
– CLEERS: evaluation protocols– Center for Nano-phase Material
Science (CNMS): catalyst synthesis
– Umicore: catalyst supplier
3 Managed by UT-Battellefor the U.S. Department of Energy
Relevance and Objectives• LNTs are attractive for the reduction of NOx emissions in both
lean-gasoline and diesel applications– No additional injection ports or reductant storage necessary
• LNTs have been introduced commercially, BUT…
HIGH COSTS AND DURABILITY LIMIT FURTHER IMPLEMENTATION
Objectives:• Investigate methods for improving performance and/or
durability of LNTs, such that PGM costs can be reduced• Determine role of individual components in a commercial LNT
during desulfation of lean NOx traps to improve understanding
4 Managed by UT-Battellefor the U.S. Department of Energy
Pt/Ce-Zr(x0.5)
Pt/Ba/Ce-Zr
Pt/MgAl2O4
Pt/Ce-Zr(x0.5)
Pt/Ba/Ce-Zr
Pt/MgAl2O4
Pt/Ce-Zr(x0.5)
Pt/Ba/Ce-Zr
Pt/MgAl2O4
Pt/Ce-Zr(x0.5)
Pt/Ba/Ce-Zr
Pt/MgAl2O4
Two-tiered Approach• Explore mixed metal oxides for storage phase of LNTs; Ba substitution• Identify material effects and attempt to correlate to performance changes• Work with CNMS (BES funded user center)• Synthesize LNTs using aqueous techniques
• Commercial catalysts are complex; made of several phases or components– Formulations derived from empirical and fundamental catalysis research
• Investigate functionality of individual components during sulfation and desulfation
BaO
BaO
CaO
BaOO
BaO
BaO
BaO
BaOO
BaO O
BaO
BaOO
BaO
BaO
BaO
BaOO
Ca
0%
20%
40%
60%
80%
100%
100 300 500 700 900
Temperature (oC)
NO
x C
onve
rsio
n
0102030405060 S released (ppm
)
Void: monolith channel
Al-rich
Ce & Zr-rich
Ba-rich
CordieriteMg & Al-rich
Void: monolith channel
Al-rich
Ce & Zr-rich
Ba-rich
CordieriteMg & Al-rich
5 Managed by UT-Battellefor the U.S. Department of Energy
Milestones for FY 2010
• Publish the collaborative effort with the Center for Nanophase Material Science on Ba-dopant effects on LNT performance (September 2010).– Submitted April 2010 to Catalysis Today
• Publish efforts on Umicore component sulfation/desulfation study (September 2010). – On target, manuscript being circulated amongst co-authors
6 Managed by UT-Battellefor the U.S. Department of Energy
Summary of Technical Accomplishments
• Confirmed the improvement in performance and desulfation properties with 5%mol Ca introduction into the BaO storage phase of an LNT catalyst
• Demonstrated sequential effect of Ca addition from 5% to 100%– Improvement is due to a synergistic effect as Ca-only catalyst
results in higher desulfation temperatures
• Determined sulfur stability and desulfation characteristics of individual components of a commercial LNT catalyst– several findings, two to be discussed– see supplemental slides for additional details
7 Managed by UT-Battellefor the U.S. Department of Energy
Impact of Dopants in Ba-based LNT Catalysts
8 Managed by UT-Battellefor the U.S. Department of Energy
Can Ba storage/release chemistry be modified by lattice substitutions?• Typical storage material is Ba-only
• BaO structure is defined by its covalent radius and charge– rBa = 2 Å– Charge in Lattice = +2
• Substituting Ba with other metals can have multiple effects on the material structure– Lattice spacing– Oxygen vacancies– Ba-vacancies
• Do nanoscale material changes affect performance?
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
BaO
BaO
BaO
BaOO
Ba-O standard structure
Different charges lead to lattice vacancies
Different radii changes lattice spacing; increases strain
BaO
BaO
CaO
BaOO
BaO
BaO
BaO
BaOO
BaO O
BaO
BaOO
BaO
BaO
BaO
BaOO
Ca
BaO O
La+3
O
BaOO
BaO
BaO
BaO
BaOO
BaO
La+3
O O
BaOO
BaO
BaO
BaO
BaOO
BaO
Ba K+1
O
BaOO
BaO
BaO
BaO
BaOO
BaO
K+1 BaO
BaOO
BaO
BaO
BaO
BaOO
9 Managed by UT-Battellefor the U.S. Department of Energy
FY2009 efforts show Ca-substitution leads to improved NSR performance and desulfation
• Ca+Ba sample yields similar NOx conversion performance to Ba-only– Some improvement at 300 and
400ºC compared to Ba-only • Ca+Ba sample releases more sulfur at
lower temperatures0
1
2
3
4
5
6
7
400 500 600 700 800 900 1000Temperature (oC)
SO2 (
umol
/gca
t-min
)
Ba-only
5%Ca+Ba
5%La+Ba
5%K+Ba
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
200°C 300°C 400°C
NO
x Con
vers
ion
(%)
Ba-only5% Ca+Ba5% K+Ba5% La+Ba
0
40
80
120
160
400-650°C 650-875°C 875-1000°C
Sulfu
r rel
ease
d ( µ
mol
/gca
t)
Ba-only5% Ca+Ba5% K+Ba5% La+Ba
Ba-only5% Ca+Ba5% K+Ba5% La+Ba
Low stability High stability Permanent
10 Managed by UT-Battellefor the U.S. Department of Energy
Ca-substitution expanded to study additional concentrations
• Same base catalyst: 1.5%wt Pt/γ-Al2O3• Ca substitution levels
– 5 mol% – 10 mol%– 20 mol%– Ca-only
• BaCO3 identified again– decreases with increasing
Ca content
• Ca-only sample results in amorphous/nanocrystallineCa-phase
10 15 20 25 30 35 40 45 502-theta (degr.)
Ba-only5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
Ba C
O3
10 15 20 25 30 35 40 45 502-theta (degr.)
Ba-only5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
Ba C
O3
NSR Pt Ba CaCatalyst (wt%) (mol%) (mol%)
Pt/Al2O3 1.5% - -Ba-only 1.1% 20% 0%
5%Ca+Ba 1.1% 19% 1%10%Ca+Ba 1.1% 18% 2%20%Ca+Ba 1.1% 16% 4%
Ca-only 1.1% 0% 20%
11 Managed by UT-Battellefor the U.S. Department of Energy
Ca-substitution continues to show some performance benefits compared to Ba• Ca-only NSR catalyst shows significantly better performance at 400ºC
– 18% greater NO converted than Ba-only
0%10%20%30%40%50%60%70%80%90%
100%
200°C 300°C 400°C
NO
x Con
vers
ion
(%)
Ba-only5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
12 Managed by UT-Battellefor the U.S. Department of Energy
Ca-only phase results in more stable sulfates; synergistic effect occurs w/ 5-10% substitution
• Sulfate at 400ºC to 5 mg S/gcat
• 5% Ca+Ba releases the most sulfur at low temperatures
5%Ca+Ba > 10%Ca+Ba > Ba-onlyBa-only > 20%Ca+Ba > Ca-only
• Ca-only has the most “high-stability” sulfates
• Since Ca substitution leads to less stable sulfates there must be a synergistic effect
0
1
2
3
4
5
6
7
400 500 600 700 800 900 1000Temperature (oC)
SO2 (
umol
/gca
t-min
) Ba-only 5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
0
40
80
120
160
400-650°C 650-875°C 875-1000°C
Sulfu
r (µm
ol/g
cat)
Ba-only 5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
0
40
80
120
160
400-650°C 650-875°C 875-1000°C
Sulfu
r (µm
ol/g
cat)
Ba-only 5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
Ba-only 5%Ca+Ba10%Ca+Ba20%Ca+BaCa-only
Low stability High stability Permanent
13 Managed by UT-Battellefor the U.S. Department of Energy
Although Ca-only has most stable sulfates, its performance is minimally impacted
• 100% Ca is most tolerant to sulfur– 10% Ca+Ba is most affected
• Sulfur tolerance is very important factor– LNT can go further between de-S– Fewer desulfations
• less fuel consumed• less impact on PGM• less initial PGM needed
• 100% Ca-storage phase is the most sulfur adsorbant storage material
• Ba-only releases the most sulfur during rich cycle at 400°C
Percentage of sulfur stored at 400°C
80%
85%
90%
95%
100%
Ba-only 5%Ca+Ba 10%Ca+Ba 20% Ca+Ba Ca-only
SO2 S
tore
d
NOx performance measured at 400°C
0%10%20%30%40%50%60%70%80%90%
100%
Ba-only 5%Ca+Ba 10%Ca+Ba 20%Ca+Ba Ca-only
NO
x C
onve
rsio
n (%
)
Initial Sulfated
14 Managed by UT-Battellefor the U.S. Department of Energy
Study of functionality of commercial LNT Components
15 Managed by UT-Battellefor the U.S. Department of Energy
Commercial LNTs are complex multicomponent devices• CLEERS reference LNT catalyst
– provided by Umicore• Ba-based sample with Pt, Pd and Rh• Relies on Al2O3, CeOx-ZrO2, and
MgAl2O4 as supports• Several groups working to understand
how some of these phases contribute to LNT performance
Void: monolith channel
Al-rich
Ce & Zr-rich
Ba-rich
CordieriteMg & Al-rich
Void: monolith channel
Al-rich
Ce & Zr-rich
Ba-rich
CordieriteMg & Al-rich
• Our focus is on sufation/desulfation:– How does Ba/Ceria-
zirconia differ from Ba/alumina?
– What is role of MgAl2O4?
TPR
16 Managed by UT-Battellefor the U.S. Department of Energy
• Umicore catalyst relies on Ceria-Zirconia as a Ba support– Alumina most widely studied
• Ceria-Zirconia is a known oxygen storage component (OSC)– Shown to have good low
temperature NOx reduction
• Sulfation studied at 400°C while cycling between lean and rich– PBA samples have sharp SO2
release profile
• Ceria-Zirconia supported catalysts trap more SO2 during cycling
Using Ceria-Zirconia vs. Alumina as a support impacts LNT chemistry
SO2 breakthrough measured while lean-rich cycling at 400°C
= Pt/Alumina= Pt/Ceria-Zirconia
012345678
0 1000 2000 3000 4000 5000Storage time (s)
Sulfu
r (pp
m)
PAPCZ
0123456789
10
0 1000 2000 3000 4000 5000Storage time (s)
Sulfu
r (pp
m)
PBAPBCZ = Pt/Ba/Ceria-Zirconia
= Pt/Ba/Alumina
0123456789
10
0 1000 2000 3000 4000 5000Storage time (s)
Sulfu
r (pp
m)
PBAPBCZ = Pt/Ba/Ceria-Zirconia
= Pt/Ba/Alumina
17 Managed by UT-Battellefor the U.S. Department of Energy
Ceria-Zirconia decreases required desulfation temperature significantly• Onset of SO2 release is lower for
Pt/Al2O3, but release profile is broad– T20% = 464°C; T90% = 704°C– Demonstrates heterogeneity of sites
• Pt/Ceria-Zirconia has sharp release profile– T20% = 494°C; T90% = 570°C
• Introducing Ba transforms release profiles– Only minor sulfur release observed
from alumina supports – PBCZ sulfur releases at significantly
lower temperature; 35-60°C• PBA: T20% = 570°C; T90% = 855°C• PBCZ: T20% = 535°C; T90% = 797°C
Sulfur release measured during 400-1000°C temperature ramp
0
2
4
6
8
10
12
14
400 500 600 700 800 900 1000Temperature (oC)
Sulfu
r (µ
mol
/gca
t-min
) PAPCZ= Pt/Ceria-Zirconia
= Pt/Alumina
0
2
4
6
8
10
12
14
400 500 600 700 800 900 1000Temperature (oC)
Sulfu
r (µ
mol
/gca
t-min
) PAPCZ= Pt/Ceria-Zirconia
= Pt/Alumina
0
1
2
3
4
5
400 500 600 700 800 900 1000Temperature (oC)
Sulfu
r (µm
ol/g
cat-m
in)
PBA
PBCZ
18 Managed by UT-Battellefor the U.S. Department of Energy
Umicore catalyst has high MgAl2O4 content but mechanism of benefit is unknown• Up to 40%wt MgAl2O4 (MA) in the washcoat• Not strongly-coordinated with platinum group metals (PGM)
• Sulfation profile on MA-only results in fast SO2 breakthrough– With PGM, it is an effective SO2 trap (PMA)
• Physical mixture of PA+MA mimics PMASO2 breakthrough measured
while lean-rich cycling at 400°C
0
5
10
15
20
25
0 1000 2000 3000 4000 5000Storage time (s)
Sulfu
r (pp
m)
PAMAPMAPA+MA MgAl2O4
Pt/Al2O3 + MgAl2O4Pt/Al2O3
Pt/MgAl2O4
19 Managed by UT-Battellefor the U.S. Department of Energy
Sulfation/Desulfation of Umicore-like sample suggests Mg-Al adsorbs SO2• PBCZ+MA most closely mimics Umicore
formulation• Additional sulfur stored on PBCZ+MA• Desulfation shows small amount of
extra SO2 released at ~800ºC– Mg-Al phase participates in sulfur
trapping and perhaps transport
0123456789
400 500 600 700 800 900 1000Temperature (oC)
Sulfu
r (µm
ol/g
cat-m
in)
PBCZPBCZ+MAMA
Indicates MgAl2O4adsorption of SO2
MgAl2O4
Pt/Ba/Ceria-Zirconia+ MgAl2O4
Pt/Ba/Ceria-Zirconia
0123456789
400 500 600 700 800 900 1000Temperature (oC)
Sulfu
r (µm
ol/g
cat-m
in)
PBCZPBCZ+MAMA
Indicates MgAl2O4adsorption of SO2
MgAl2O4
Pt/Ba/Ceria-Zirconia+ MgAl2O4
Pt/Ba/Ceria-Zirconia
0123456789
10
0 1000 2000 3000 4000 5000Storage time (s)
Sulfu
r (pp
m)
PBCZPBCZ+MA
= Pt/Ba/Ceria-Zirconia= Pt/Ba/Ceria-Zirconia + MgAl2O4
20 Managed by UT-Battellefor the U.S. Department of Energy
Collaborators and Partners
• CLEERS– Discussions and evaluations protocols
• Umicore– Catalyst supplier for the commercial LNT
• Center for Nanophase Materials Science (CNMS)– Basic Energy Science funded user facility at ORNL– Prepared doped storage materials – Performed materials characterization
• High Temperature Materials Laboratory (HTML)– ORNL user facility funded by EERE – Additional materials characterization
21 Managed by UT-Battellefor the U.S. Department of Energy
Future Directions (Beyond FY10)• Increase materials characterization efforts to link performance effects to material
property– Will rely on HTML user center proposals– Implement DRIFTS studies to look at Ca impact on nitrate/sulfate bonding effects
• Effects of durability– Is benefit maintained after several thermal cycles or do the phases separate– Repeated sulfation/desulfation cycles
• Only desulfate to typical desulfation temperatures, i.e. 700°C
• Support effects– Umicore component effort suggest changing support would affect results– Study Ceria-Zirconia versus Alumina
• Multicomponent studies Tertiary oxides– Very interesting work recently reported from GM regarding doped perovskites
with drastically reduced PGM levels
22 Managed by UT-Battellefor the U.S. Department of Energy
Summary• Relevance:
– LNTs are attractive for the reduction of NOx emissions in both lean-gasoline and diesel applications
– High costs and durability limit further implementation of LNTs • Approach:
– Investigate novel formulations to guide material discovery and improve LNTs– Investigate functionality of individual components of commercial catalysts during
sulfation and desulfation• Collaborations:
– Umicore catalyst supplier and collaboration with other VTP projects: CLEERS, PSAT, CRADAs, UK-CAER
– BES-funded Center for Nanophase Materials Science (CNMS)• Technical Accomplishments:
– Demonstrated benefits of the addition of Ca-dopants to LNT storage phase– Identified functionality of components of a commercial LNT catalyst
• Future Work:– Increase materials characterization to help guide materials models for doped LNTs– Investigate support effects of Ca-doped samples; particularly ceria-zirconia– Explore low PGM catalysts tertiary oxide materials (GM-reported doped pervoskites)
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