| 1 - 1 |
Catalytic Control of Lean-Burn Engine Exhaust Emissions Preface
Yezerets A, Peden C, Szanyi J, Nova I, Epling B |
| 2 - 7 |
Characteristics of Pt-K/MgAl2O4 lean NOx trap catalysts
Kim DH, Mudiyanselage K, Szanyi J, Zhu H, Kwak JH, Peden CHF |
| 8 - 19 |
In situ FTIR investigation of the role of surface isocyanates in the reduction of NOX by CO and C3H6 over model Pt/BaO/Al2O3 and Rh/BaO/Al2O3 NOX storage and reduction (NSR) catalysts
DiGiulio CD, Komvokis VG, Amiridis MD |
| 20 - 26 |
Spatiotemporal distribution of NOx storage and impact on NH3 and N2O selectivities during lean/rich cycling of a Ba-based lean NOx trap catalyst
Choi JS, Partridge WP, Pihl JA, Kim MY, Koci P, Daw CS |
| 27 - 42 |
Crystallite-Scale Model for NOx Storage and Reduction on Pt/BaO/Al2O3: Pt Dispersion Effects on NOx Conversion and Ammonia Selectivity
Shakya BM, Harold MP, Balakotaiah V |
| 43 - 53 |
Elucidating NH3 formation during NOx reduction by CO on Pt-BaO/Al2O3 in excess water
Dasari PR, Muncrief R, Harold MP |
| 54 - 71 |
SOx uptake and release properties of TiO2/Al2O3 and BaO/TiO2/Al2O3 mixed oxide systems as NOx storage materials
Senturk GS, Vovk EI, Zaikovskii VI, Say Z, Soylu AM, Bukhtiyarov VI, Ozensoy E |
| 72 - 77 |
Pt-free, LaMnO3 based lean NOx trap catalysts
Qi GS, Li W |
| 78 - 82 |
NOx storage/reduction over alkali-metal-nitrate impregnated titanate nanobelt catalysts and investigation of alkali metal cation migration using XPS
Yoshida A, Shen WH, Eda T, Watanabe R, Ito T, Naito S |
| 83 - 94 |
LNT plus in situ SCR catalyst system for diesel emissions control
Xu L, McCabe RW |
| 95 - 106 |
Enhanced NOx reduction and byproduct removal by (HC plus OHC)/SCR over multifunctional dual-bed monolith catalyst
Kim MK, Kim PS, Cho BK, Nam IS, Oh SH |
| 107 - 114 |
FTIR in situ mechanistic study of the NH3-NO/NO2 "Fast SCR" reaction over a commercial Fe-ZSM-5 catalyst
Ruggeri MP, Grossale A, Nova I, Tronconi E, Jirglova H, Sobalik Z |
| 115 - 128 |
Experimental and kinetic modeling study of NO oxidation: Comparison of Fe and Cu-zeolite catalysts
Metkar PS, Balakotaiah V, Harold MP |
| 129 - 144 |
Integrated operando X-ray absorption and DFT characterization of Cu-SSZ-13 exchange sites during the selective catalytic reduction of NOx with NH3
McEwen JS, Anggara T, Schneider WF, Kispersky VF, Miller JT, Delgass WN, Ribeiro FH |
| 145 - 152 |
Influence of calcination temperature on Fe/HBEA catalyst for the selective catalytic reduction of NOx with NH3
Ma L, Li JH, Arandiyan H, Shi WB, Liu CX, Fu LX |
| 153 - 159 |
Effect of operating variables on the enhanced SCR reaction over a commercial V2O5-WO3/TiO2 catalyst for stationary applications
Forzatti P, Nova I, Tronconi E, Kustov A, Thogersen JR |
| 160 - 165 |
An environmentally-benign CeO2-TiO2 catalyst for the selective catalytic reduction of NOx with NH3 in simulated diesel exhaust
Shan WP, Liu FD, He H, Shi XY, Zhang CB |
| 166 - 177 |
Mechanistic investigation of ethanol SCR of NOx over Ag/Al(2)O3
Johnson WL, Fisher GB, Toops TJ |
| 178 - 183 |
Synthesis, characterization and CO oxidation of TiO2/(La,Sr)MnO3 composite nanorod array
Guo YB, Zhang ZH, Ren Z, Gao HY, Gao PX |
| 184 - 191 |
Pd-integrated perovskites for TWC applications: Synthesis, microstructure and N2O-selectivity
Rodriguez GCM, Kelm K, Heikens S, Grunert W, Saruhan B |
| 192 - 196 |
Alternative alkali resistant deNO(x) catalysts
Putluru SSR, Kristensen SB, Due-Hansen J, Riisager A, Fehrmann R |
| 197 - 204 |
Deactivation mechanisms of Pt/Pd-based diesel oxidation catalysts
Wiebenga MH, Kim CH, Schmieg SJ, Oh SH, Brown DB, Kim DH, Lee JH, Peden CHF |
| 205 - 218 |
Investigation of the effects of biodiesel-based Na on emissions control components
Brookshear DW, Nguyen K, Toops TJ, Bunting BG, Rohr WF, Howe J |
| 219 - 226 |
The interaction between supported Rh- and Nd2O3-enriched surface layer on ZrO2 for Rh sintering suppression
Tanabe T, Morikawa A, Hatanaka M, Takahashi N, Nagai Y, Sato A, Kuno O, Suzuki H, Shinjoh H |
| 227 - 236 |
Improved high temperature stability of NH3-SCR catalysts based on rare earth vanadates supported on TiO2-WO3-SiO2
Casanova M, Schermanz K, Llorca J, Trovarelli A |
| 237 - 244 |
Thermal and chemical aging of model three-way catalyst Pd/Al2O3 and its impact on the conversion of CNG vehicle exhaust
Matam SK, Otal EH, Aguirre MH, Winkler A, Ulrich A, Rentsch D, Weidenkaff A, Ferri D |
| 245 - 251 |
Possible origin of improved high temperature performance of hydrothermally aged Cu/beta zeolite catalysts
Peden CHF, Kwak JH, Burton SD, Tonkyn RG, Kim DH, Lee JH, Jen HW, Cavataio G, Cheng YS, Lambert CK |
| 252 - 261 |
Thermal durability of Cu-CHA NH3-SCR catalysts for diesel NOx reduction
Schmieg SJ, Oh SH, Kim CH, Brown DB, Lee JH, Peden CHF, Kim DH |
| 262 - 270 |
The effects of high temperature lean exposure on the subsequent HC conversion of automotive catalysts
Theis JR, McCabe RW |
| 271 - 278 |
Interaction between soot and stored NOx during operation of LNT Pt-Ba/Al2O3 catalysts
Matarrese R, Artioli N, Castoldi L, Lietti L, Forzatti P |
| 279 - 287 |
Synthesis and catalytic properties of CeO2 and Co/CeO2 nanofibres for diesel soot combustion
Kumar PA, Tanwar MD, Russo N, Pirone R, Fino D |
| 288 - 300 |
Comparative study of nanometric Co-, Mn- and Fe-based perovskite-type complex oxide catalysts for the simultaneous elimination of soot and NOx from diesel engine exhaust
Wang H, Liu J, Zhao Z, Wei YC, Xu CM |
