The promoting/inhibiting effect of water vapor on the selective catalytic reduction of NOx.
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[1] N. Yan,et al. Understanding the Water Effect for Selective Catalytic Reduction of NOx with NH3 over Cu-SSZ-13 Catalysts , 2022, ACS ES&T Engineering.
[2] Guohua Jing,et al. Enhancement of SO2 Resistance on Submonolayer V2O5–MnO2/CeO2 Catalyst by Three-Dimensional Ordered Mesoporous CeO2 in Low-Temperature NH3–SCR , 2022, Energy & Fuels.
[3] Guodong Zhang,et al. The water resistance enhanced strategy of Mn based SCR catalyst by construction of TiO2 shell and superhydrophobic coating , 2021 .
[4] D. Che,et al. Review on the Selective Catalytic Reduction of NO with H2 by Using Novel Catalysts , 2021, Journal of Environmental Chemical Engineering.
[5] F. Gao,et al. Recent advances in hybrid metal oxide–zeolite catalysts for low-temperature selective catalytic reduction of NOx by ammonia , 2021 .
[6] J. Kondo,et al. Construction of Fe2O3 loaded and mesopore confined thin-layer titania catalyst for efficient NH3-SCR of NOx with enhanced H2O/SO2 tolerance , 2021 .
[7] Donghai Mei,et al. Water: A promoter of ammonia selective catalytic reduction over copper-exchanged LTA zeolites , 2021 .
[8] Jingfang Sun,et al. Conquering ammonium bisulfate poison over low-temperature NH3-SCR catalysts: A critical review , 2021 .
[9] M. Wey,et al. Preferred enhancement of fast-SCR by Mn/CeSiOx catalyst: Study on Ce/Si promotion and shape dependence , 2021 .
[10] Haosen Zhou,et al. NO selective catalytic reduction with propylene over one-pot synthesized Fe-SAPO-34 catalyst under diesel exhaust conditions , 2020 .
[11] A. M. Efstathiou,et al. Remarkable N2-selectivity enhancement of practical NH3-SCR over Co0.5Mn1Fe0.25Al0.75Ox-LDO: The role of Co investigated by transient kinetic and DFT mechanistic studies , 2020, Applied Catalysis B: Environmental.
[12] X. Bi,et al. One-pot synthesis of FeCu-SSZ-13 zeolite with superior performance in selective catalytic reduction of NO by NH3 from natural aluminosilicates , 2020 .
[13] Yadong Li,et al. Challenges and opportunities for manganese oxides in low-temperature selective catalytic reduction of NOx with NH3: H2O resistance ability , 2020 .
[14] Dingsheng Wang,et al. A MnO2-based catalyst with H2O resistance for NH3-SCR: Study of catalytic activity and reactants-H2O competitive adsorption , 2020 .
[15] A. Serrano-Lotina,et al. MnO2-supported catalytic bodies for selective reduction of NO with NH3: Influence of NO2 and H2O , 2020 .
[16] Yongmin Huang,et al. Nanosheets-assembled Ni (Co) doped CeO2 microspheres toward NO + CO reaction , 2020 .
[17] Jianjun Chen,et al. The poisoning mechanism of gaseous HCl on low-temperature SCR catalysts: MnO −CeO2 as an example , 2020 .
[18] Qinfang Zhang,et al. The role of the Cu dopant on a Mn3O4 spinel SCR catalyst: Improvement of low-temperature activity and sulfur resistance , 2020 .
[19] Zhaoliang Zhang,et al. Enhancement of low-temperature NH3-SCR catalytic activity and H2O & SO2 resistance over commercial V2O5-MoO3/TiO2 catalyst by high shear-induced doping of expanded graphite , 2020 .
[20] Zhixian Gao,et al. High coverage H2O adsorption on CuAl2O4 surface: A DFT study , 2020 .
[21] Fulong Yuan,et al. Influence of Sm on the low temperature NH3-SCR of NO activity and H2O/SO2 resistance over the SmaMnNi2Ti7Ox (a = 0.1, 0.2, 0.3, 0.4) catalysts , 2020 .
[22] Ze Zhang,et al. Visualizing H2O molecules reacting at TiO2 active sites with transmission electron microscopy , 2020, Science.
[23] Tingyu Zhu,et al. A review of the catalysts used in the reduction of NO by CO for gas purification , 2020, Environmental Science and Pollution Research.
[24] J. Crittenden,et al. Irregular influence of alkali metals on Cu-SAPO-34 catalyst for selective catalytic reduction of NOx with ammonia. , 2019, Journal of hazardous materials.
[25] Xuesen Du,et al. Promoting effects of water on the NH3-SCR reaction over Cu-SAPO-34 catalysts: transient and permanent influences on Cu species. , 2019, Dalton transactions.
[26] Qingling Liu,et al. Novel Mn Zr Cr O catalysts for low temperature NH3-SCR derived from high H2O content flue gas via natural gas combustion , 2019 .
[27] Sihui Zhan,et al. Relationship between structure and performance of a novel highly dispersed MnOx on Co-Al layered double oxide for low temperature NH3-SCR , 2019 .
[28] Bichun Huang,et al. Research progress, challenges and perspectives on the sulfur and water resistance of catalysts for low temperature selective catalytic reduction of NOx by NH3 , 2019, Applied Catalysis A: General.
[29] A. M. Efstathiou,et al. Promotional effect of Ce doping in Cu4Al1Ox – LDO catalyst for low-T practical NH3-SCR: Steady-state and transient kinetics studies , 2019, Applied Catalysis B: Environmental.
[30] Kuo Liu,et al. The effects of H2O on a vanadium-based catalyst for NH3-SCR at low temperatures: a quantitative study of the reaction pathway and active sites , 2019, Catalysis Science & Technology.
[31] Guodong Zhang,et al. Enhancing Water Resistance of Mn-based Catalyst for Low Temperature SCR Reaction by Modifying Super Hydrophobic Layer. , 2019, ACS applied materials & interfaces.
[32] Liyi Shi,et al. Selective Catalytic Reduction of NOx with NH3 by Using Novel Catalysts: State of the Art and Future Prospects. , 2019, Chemical reviews.
[33] Jingfang Sun,et al. Enhancing the deNO performance of MnO /CeO2-ZrO2 nanorod catalyst for low-temperature NH3-SCR by TiO2 modification , 2019, Chemical Engineering Journal.
[34] P. Ning,et al. Significant promoting effect of Ce or La on the hydrothermal stability of Cu-SAPO-34 catalyst for NH3-SCR reaction , 2019, Chemical Engineering Journal.
[35] Fulong Yuan,et al. Effect of W on the acidity and redox performance of the Cu0.02Fe0.2W TiOx (a = 0.01, 0.02, 0.03) catalysts for NH3-SCR of NO , 2019, Applied Catalysis B: Environmental.
[36] Hong He,et al. Polytetrafluoroethylene modifying: A low cost and easy way to improve the H2O resistance ability over MnOx for low-temperature NH3-SCR , 2019, Journal of Environmental Chemical Engineering.
[37] Tao Wu,et al. Promotion effect and mechanism of the addition of Mo on the enhanced low temperature SCR of NOx by NH3 over MnOx/γ-Al2O3 catalysts , 2019, Applied Catalysis B: Environmental.
[38] Cheng Zhang,et al. A novel highly active and sulfur resistant catalyst from Mn-Fe-Al layered double hydroxide for low temperature NH3-SCR , 2019, Catalysis Today.
[39] Donghai Mei,et al. Unraveling the mysterious failure of Cu/SAPO-34 selective catalytic reduction catalysts , 2019, Nature Communications.
[40] Dequan Fan,et al. Water mediated oxygen activation in NH3 SCR reaction over a Cu-SAPO-34 catalyst: a first principles study , 2019, Catalysis Science & Technology.
[41] Chenghang Zheng,et al. New insight into alkali resistance and low temperature activation on vanadia-titania catalysts for selective catalytic reduction of NO , 2019, Applied Surface Science.
[42] Haidi Xu,et al. Investigation of the selective catalytic reduction of NO with NH3 over the WO3/Ce0.68Zr0.32O2 catalyst: the role of H2O in SO2 inhibition , 2019, New Journal of Chemistry.
[43] Kuo Liu,et al. Quantitative study of the NH3-SCR pathway and the active site distribution over CeWO at low temperatures , 2019, Journal of Catalysis.
[44] Chunyuan Ma,et al. NO reduction by CO over copper catalyst supported on mixed CeO2 and Fe2O3: Catalyst design and activity test , 2018, Applied Catalysis B: Environmental.
[45] C. Zhang,et al. Synthesis and catalytic performance of Cu1Mn0.5Ti0.5O mixed oxide as low-temperature NH3-SCR catalyst with enhanced SO2 resistance , 2018, Applied Catalysis B: Environmental.
[46] Bucheng Li,et al. Scalable Preparation of Superamphiphobic Coatings with Ultralow Sliding Angles and High Liquid Impact Resistance. , 2018, ACS applied materials & interfaces.
[47] D. Bianchi,et al. Experimental Microkinetic Approach of De-NOx by NH3 on V2O5/WO3/TiO2 Catalysts. 6. NH3–H2O Coadsorption on TiO2-Based Solids and Competitive Temkin Model , 2018, The Journal of Physical Chemistry C.
[48] W. Shangguan,et al. Water promotion mechanism on the NH3-SCR over Fe-BEA catalyst , 2018, Catalysis Communications.
[49] Yanming Cui,et al. Role of CTAB in the improved H2O resistance for selective catalytic reduction of NO with NH3 over iron titanium catalyst , 2018, Chemical Engineering Journal.
[50] C. Niu,et al. Gd-modified MnOx for the selective catalytic reduction of NO by NH3: The promoting effect of Gd on the catalytic performance and sulfur resistance , 2018, Chemical Engineering Journal.
[51] Xiang Li,et al. Interaction of phosphorus with a FeTiOx catalyst for selective catalytic reduction of NOx with NH3: Influence on surface acidity and SCR mechanism , 2018, Chemical Engineering Journal.
[52] H. A. Duarte,et al. Stability, Structural, and Electronic Properties of Hausmannite (Mn3O4) Surfaces and Their Interaction with Water , 2018, The Journal of Physical Chemistry C.
[53] J. Hao,et al. Extraordinary Deactivation Offset Effect of Arsenic and Calcium on CeO2-WO3 SCR Catalysts. , 2018, Environmental science & technology.
[54] Junhua Li,et al. New Insight into SO2 Poisoning and Regeneration of CeO2-WO3/TiO2 and V2O5-WO3/TiO2 Catalysts for Low-Temperature NH3-SCR. , 2018, Environmental science & technology.
[55] Minghui Zhu,et al. Formation of N2O greenhouse gas during SCR of NO with NH3 by supported vanadium oxide catalysts , 2018 .
[56] Xinyong Li,et al. 2D, 3D mesostructured silicas templated mesoporous manganese dioxide for selective catalytic reduction of NOx with NH3. , 2018, Journal of colloid and interface science.
[57] Yunbo Yu,et al. A Low-Temperature Route Triggered by Water Vapor during the Ethanol-SCR of NOx over Ag/Al2O3 , 2018 .
[58] Kaiwen Zha,et al. Facile and template-free fabrication of mesoporous 3D nanosphere-like MnxCo3−xO4 as highly effective catalysts for low temperature SCR of NOx with NH3 , 2018 .
[59] Youlin Liu,et al. Novel CeMoxOy-clay hybrid catalysts with layered structure for selective catalytic reduction of NOx by NH3 , 2018, RSC advances.
[60] C. Niu,et al. Sulfur and Water Resistance of Mn-Based Catalysts for Low-Temperature Selective Catalytic Reduction of NOx: A Review , 2018 .
[61] Jiaxiu Guo,et al. Study of NO removal and resistance to SO2 and H2O of MnOx/TiO2, MnOx/ZrO2 and MnOx/ZrO2–TiO2 , 2017 .
[62] Krishna Kamasamudram,et al. Influence of phosphorus on Cu-SSZ-13 for selective catalytic reduction of NOx by ammonia , 2017 .
[63] M. Goldbach,et al. Urea Decomposition in Selective Catalytic Reduction on V2O5/WO3/TiO2 Catalyst in Diesel Exhaust , 2017 .
[64] U. Tumuluri,et al. Nature of Active Sites and Surface Intermediates during SCR of NO with NH₃ by Supported V₂O₅--WO₃/TiO₂ Catalysts. , 2017, Journal of the American Chemical Society.
[65] C. Niu,et al. MnM2O4 microspheres (M = Co, Cu, Ni) for selective catalytic reduction of NO with NH3: Comparative study on catalytic activity and reaction mechanism via in-situ diffuse reflectance infrared Fourier transform spectroscopy , 2017 .
[66] Bing Li,et al. Impacts of Pb and SO2 Poisoning on CeO2-WO3/TiO2-SiO2 SCR Catalyst. , 2017, Environmental science & technology.
[67] S. Hong,et al. The Origin of an Unexpected Increase in NH3–SCR Activity of Aged Cu-LTA Catalysts , 2017 .
[68] Rui Wang,et al. A novel ring-like Fe2O3-based catalyst: Tungstophosphoric acid modification, NH3-SCR activity and tolerance to H2O and SO2 , 2017 .
[69] Sicong Ma,et al. Mechanistic Study of Selective Catalytic Reduction of NOx with NH3 over Mn-TiO2: A Combination of Experimental and DFT Study , 2017 .
[70] G. Pacchioni,et al. H2O Adsorption on WO3 and WO3-x (001) Surfaces. , 2017, ACS applied materials & interfaces.
[71] Chunyuan Ma,et al. Improvement in the Water Tolerance of SiO2-Modified Semicoke Catalysts for the Low-Temperature NO + CO Reaction , 2017 .
[72] Jianpeng Shi,et al. Rationally Designed Porous MnOx-FeOx Nanoneedles for Low-Temperature Selective Catalytic Reduction of NOx by NH3. , 2017, ACS applied materials & interfaces.
[73] Donghai Mei,et al. Selective Catalytic Reduction over Cu/SSZ-13: Linking Homo- and Heterogeneous Catalysis. , 2017, Journal of the American Chemical Society.
[74] Jihui Wang,et al. Recent advances in the selective catalytic reduction of NOx with NH3 on Cu-Chabazite catalysts , 2017 .
[75] Zhichun Si,et al. Evolution of copper species on Cu/SAPO-34 SCR catalysts upon hydrothermal aging , 2017 .
[76] P. G. Moses,et al. A complete reaction mechanism for standard and fast selective catalytic reduction of nitrogen oxides on low coverage VOx/TiO2(0 0 1) catalysts , 2017 .
[77] Chunyuan Ma,et al. Investigation on Fe-Co binary metal oxides supported on activated semi-coke for NO reduction by CO , 2017 .
[78] Tingting Li,et al. Highly efficient Pd-doped aluminate spinel catalysts with different divalent cations for the selective catalytic reduction of NO with H2 at low temperature , 2017 .
[79] Lihui Dong,et al. The influence of Mn-doped CeO 2 on the activity of CuO/CeO 2 in CO oxidation and NO + CO model reaction , 2016 .
[80] A. Salker,et al. Catalytic activity and mechanistic approach of NO reduction by CO over M 0.05 Co 2.95 O 4 (M = Rh, Pd & Ru) spinel system , 2016 .
[81] T. Grzybek,et al. The influence of the promotion of N-modified activated carbon with iron on NO removal by NH3-SCR (Selective catalytic reduction) , 2016 .
[82] Z. Zhong,et al. NH3-SCR Performance of Mn-Fe/TiO2 Catalysts at Low Temperature in the Absence and Presence of Water Vapor , 2016, Water, Air, & Soil Pollution.
[83] D. Ferri,et al. The Significance of Lewis Acid Sites for the Selective Catalytic Reduction of Nitric Oxide on Vanadium-Based Catalysts. , 2016, Angewandte Chemie.
[84] Weixin Zou,et al. A general and inherent strategy to improve the water tolerance of low temperature NH3-SCR catalysts via trace SiO2 deposition , 2016 .
[85] C. Niu,et al. Manganese oxide-based catalysts for low-temperature selective catalytic reduction of NOx with NH3: A review , 2016 .
[86] Chunya Wu,et al. A DFT study of water adsorption on rutile TiO2 (110) surface: The effects of surface steps. , 2016, The Journal of chemical physics.
[87] Liyi Shi,et al. Promotional effects of zirconium doped CeVO4 for the low-temperature selective catalytic reduction of NOx with NH3 , 2016 .
[88] Shijian Yang,et al. Effect of H2O and SO2 on the Selective Catalytic Reduction of NO with NH3 Over Ce/TiO2 Catalyst: Mechanism and Kinetic Study , 2016 .
[89] Wei Sun,et al. Selective catalytic reduction of nitric oxide by hydrogen over NiFe2-xPdxO4 catalysts at low temperature. , 2016 .
[90] J. Hao,et al. Design Strategies for CeO2-MoO3 Catalysts for DeNOx and Hg(0) Oxidation in the Presence of HCl: The Significance of the Surface Acid-Base Properties. , 2015, Environmental science & technology.
[91] Xinxin Li,et al. The ordered mesoporous transition metal oxides for selective catalytic reduction of NOx at low temperature , 2015 .
[92] G. Lu,et al. A Highly Effective Catalyst of Sm-MnOx for the NH3-SCR of NOx at Low Temperature: Promotional Role of Sm and Its Catalytic Performance , 2015 .
[93] Dong Wook Kwon,et al. Influence of tungsten on the activity of a Mn/Ce/W/Ti catalyst for the selective catalytic reduction of NO with NH3 at low temperatures , 2015 .
[94] Kuo Liu,et al. Significant Promotion Effect of Mo Additive on a Novel Ce-Zr Mixed Oxide Catalyst for the Selective Catalytic Reduction of NO(x) with NH3. , 2015, ACS applied materials & interfaces.
[95] Shijian Yang,et al. The mechanism of the effect of H2O on the low temperature selective catalytic reduction of NO with NH3 over Mn–Fe spinel , 2015 .
[96] Tie Yu,et al. The influence of CO2 and H2O on selective catalytic reduction of NO by NH3 over Cu/SAPO-34 catalyst , 2015 .
[97] Shijian Yang,et al. Novel Effect of H2O on the Low Temperature Selective Catalytic Reduction of NO with NH3 over MnOx—CeO2: Mechanism and Kinetic Study , 2015 .
[98] Sihui Zhan,et al. Facile preparation of ordered mesoporous MnCo2O4 for low-temperature selective catalytic reduction of NO with NH3. , 2015, Nanoscale.
[99] Xiaolong Tang,et al. Low-temperature selective catalytic reduction of NOX with NH3 over cerium and manganese oxides supported on TiO2–graphene , 2015 .
[100] P. Millington,et al. Formation of reactive Lewis acid sites on Fe/WO3–ZrO2 catalysts for higher temperature SCR applications , 2015 .
[101] G. Landi,et al. Adsorption and co-adsorption of NO and water on LaCu-ZSM5 , 2014 .
[102] Zhongbiao Wu,et al. Manganese–niobium mixed oxide catalyst for the selective catalytic reduction of NOx with NH3 at low temperatures , 2014 .
[103] P. Blakeman,et al. The role of pore size on the thermal stability of zeolite supported Cu SCR catalysts , 2014 .
[104] Liyi Shi,et al. Porous Ni-Mn oxide nanosheets in situ formed on nickel foam as 3D hierarchical monolith de-NO(x) catalysts. , 2014, Nanoscale.
[105] Liyi Shi,et al. Rational Design of High-Performance DeNOx Catalysts Based on MnxCo3–xO4 Nanocages Derived from Metal–Organic Frameworks , 2014 .
[106] K. Mathisen,et al. On the Promoting Effect of Water during NOx Removal over Single-Site Copper in Hydrophobic Silica APD-Aerogels , 2014 .
[107] F. Xiao,et al. Excellent performance of one-pot synthesized Cu-SSZ-13 catalyst for the selective catalytic reduction of NOx with NH3. , 2014, Environmental science & technology.
[108] Peter N. R. Vennestrøm,et al. Influence of lattice stability on hydrothermal deactivation of Cu-ZSM-5 and Cu-IM-5 zeolites for selective catalytic reduction of NOx by NH3 , 2014 .
[109] D. Weng,et al. Migration of Cu species in Cu/SAPO-34 during hydrothermal aging , 2013 .
[110] Liyi Shi,et al. Low-temperature selective catalytic reduction of NO with NH₃ over nanoflaky MnOx on carbon nanotubes in situ prepared via a chemical bath deposition route. , 2013, Nanoscale.
[111] Di Wang,et al. In Situ-DRIFTS Study of Selective Catalytic Reduction of NOx by NH3 over Cu-Exchanged SAPO-34 , 2013 .
[112] K. Cen,et al. Experimental and theoretical studies on the influence of water vapor on the performance of a Ce-Cu-Ti oxide SCR catalyst , 2013 .
[113] Yan Yao,et al. A comparative study of Mn/CeO2, Mn/ZrO2 and Mn/Ce-ZrO2 for low temperature selective catalytic reduction of NO with NH3 in the presence of SO2 and H2O. , 2013, Journal of environmental sciences.
[114] Liyi Shi,et al. Highly dispersed CeO2 on carbon nanotubes for selective catalytic reduction of NO with NH3 , 2013 .
[115] Liyi Shi,et al. In situ supported MnO(x)-CeO(x) on carbon nanotubes for the low-temperature selective catalytic reduction of NO with NH3. , 2013, Nanoscale.
[116] Biaohua Chen,et al. Influence of H2O on the low-temperature NH3-SCR of NO over V2O5/AC catalyst: An experimental and modeling study , 2013 .
[117] W. Li,et al. The influence of silicon on the catalytic properties of Cu/SAPO-34 for NOx reduction by ammonia-SCR , 2012 .
[118] Zhiwei Huang,et al. Effect of H2O on catalytic performance of manganese oxides in NO reduction by NH3 , 2012 .
[119] G. Russo,et al. Effect of water on NO adsorption over Cu-ZSM-5 based catalysts , 2012 .
[120] M. Bruns,et al. NOx reduction by H2 on WOx/ZrO2-supported Pd catalysts under lean conditions , 2012 .
[121] P. Smirniotis,et al. Nickel-doped Mn/TiO2 as an efficient catalyst for the low-temperature SCR of NO with NH3: Catalytic evaluation and characterizations , 2012 .
[122] Ja Hun Kwak,et al. Effects of hydrothermal aging on NH3-SCR reaction over Cu/zeolites , 2012 .
[123] M. Skoglundh,et al. Effect of Thermal Ageing on the Nature of Iron Species in Fe-BEA , 2012, Catalysis Letters.
[124] A. M. Efstathiou,et al. Industrial NOx control via H2-SCR on a novel supported-Pt nanocatalyst , 2011 .
[125] Raul F. Lobo,et al. The ammonia selective catalytic reduction activity of copper-exchanged small-pore zeolites , 2011 .
[126] H. Bi,et al. Effects of O2, CO2 and H2O on NOx adsorption and selective catalytic reduction over Fe/ZSM-5 , 2011 .
[127] K. Wilson,et al. Carbon nanotube-supported metal catalysts for NOx reduction using hydrocarbon reductants. Part 1: Catalyst preparation, characterization and NOx reduction characteristics , 2011 .
[128] O. Kröcher,et al. Hydrothermal deactivation of Fe-ZSM-5 catalysts for the selective catalytic reduction of NO with NH3 , 2011 .
[129] Kinga Skalska,et al. Trends in NO(x) abatement: a review. , 2010, The Science of the total environment.
[130] Hong He,et al. Selective catalytic reduction of NO with NH3 over manganese substituted iron titanate catalyst: Reaction mechanism and H2O/SO2 inhibition mechanism study , 2010 .
[131] H. Hamada,et al. Promotional role of H2O in the selective catalytic reduction of NO with CO over Ir/WO3/SiO2 catalyst , 2010 .
[132] M. Szaleniec,et al. Molecular and dissociative adsorption of water at low-index V2O5 surfaces: DFT studies using cluster surface models , 2010 .
[133] Shiqiu Gao,et al. Sulfur poisoning resistant mesoporous Mn-base catalyst for low-temperature SCR of NO with NH3 , 2010 .
[134] V. I. Avdeev,et al. Water Effect on the Electronic Structure of Active Sites of Supported Vanadium Oxide Catalyst VOx/TiO2(001) , 2010 .
[135] B. Saruhan,et al. Effect of Fe/Co-ratio on the phase composition of Pd-integrated perovskites and its H2-SCR of NOx performance , 2010 .
[136] O. Kröcher,et al. Screening of doped MnOx–CeO2 catalysts for low-temperature NO-SCR , 2009 .
[137] H. Hamada,et al. Promoting Effect of Coexisting H2O on the Activity of Ir/WO3/SiO2 Catalyst for the Selective Reduction of NO with CO , 2008 .
[138] B. Sels,et al. The catalytic performance of Cu-containing zeolites in N2O decomposition and the influence of O2, NO and H2O on recombination of oxygen , 2008 .
[139] Ji-hui Huang,et al. Selective catalytic reduction of NO with NH3 at low temperatures over iron and manganese oxides supported on mesoporous silica , 2008 .
[140] A. Satsuma,et al. Involvement of NCO species in promotion effect of water vapor on propane-SCR over Co-MFI zeolite , 2007 .
[141] P. Boolchand,et al. Surface characterization studies of TiO2 supported manganese oxide catalysts for low temperature SCR of NO with NH3 , 2007 .
[142] C. Costa,et al. Industrial H2-SCR of NO on a novel Pt/MgO–CeO2 catalyst , 2007 .
[143] C. Costa,et al. Low-temperature H2-SCR of NO on a novel Pt/MgO-CeO2 catalyst , 2007 .
[144] M. Twigg. Progress and future challenges in controlling automotive exhaust gas emissions , 2007 .
[145] S. Suárez,et al. Nitrous oxide formation in low temperature selective catalytic reduction of nitrogen oxides with V2O5/TiO2 catalysts , 2007 .
[146] J. Pinilla,et al. NH3-SCR of NO at low temperatures over sulphated vanadia on carbon-coated monoliths: Effect of H2O and SO2 traces in the gas feed , 2006 .
[147] I. Nam,et al. Characteristics of copper ion exchanged mordenite catalyst deactivated by HCl for the reduction of NOx with NH3 , 2006 .
[148] Zhenyu Liu,et al. Inhibition effect of H2O on V2O5/AC catalyst for catalytic reduction of NO with NH3 at low temperature , 2006 .
[149] Zhiguang Guo,et al. Stable biomimetic super-hydrophobic engineering materials. , 2005, Journal of the American Chemical Society.
[150] E. Jobson,et al. Cu-ZSM-5 zeolite highly active in reduction of NO with decane under water vapor presence: Comparison of decane, propane and propene by in situ FTIR , 2005 .
[151] V. Grassian,et al. An FT-IR Study of NO2 Reduction in Nanocrystalline NaY Zeolite: Effect of Zeolite Crystal Size and Adsorbed Water , 2005 .
[152] A. Sierraalta,et al. Density functional study of the interaction of Cu+ ion-exchanged zeolites with H2O and SO2 molecules , 2005 .
[153] C. Marshall,et al. Coated bifunctional catalysts for NOx SCR with C3H6: Part II. In situ spectroscopic characterization , 2004 .
[154] Hideaki Hamada,et al. Mechanistic study of the effect of coexisting H2O on the selective reduction of NO with propene over sol–gel prepared In2O3-Al2O3 catalyst , 2003 .
[155] I. Nam,et al. Effect of Pd on the water tolerance of Co-ferrierite catalyst for NO reduction by CH4 , 2003 .
[156] Z. Sobalík,et al. Redox catalysis over metallo-zeolites Contribution to environmental catalysis , 2003 .
[157] Zhenyu Liu,et al. Combined Effect of H2O and SO2 on V2O5/AC Catalysts for NO Reduction with Ammonia at Lower Temperatures , 2002 .
[158] K. Polychronopoulou,et al. An Investigation of the NO/H2/O2 (Lean De-NOx) Reaction on a Highly Active and Selective Pt/La0.7Sr0.2Ce0.1FeO3 Catalyst at Low Temperatures , 2002 .
[159] Alexander Wokaun,et al. Side Reactions in the Selective Catalytic Reduction of NOx with Various NO2 Fractions , 2002 .
[160] A. Satsuma,et al. Promoting Effect of Water Vapor on the Catalytic Activity of Cobalt-Exchanged MFI Zeolite for the Selective Reduction of NO by C3H8 , 2001 .
[161] K. Shimizu,et al. Catalytic performance of Ag-Al2O3 catalyst for the selective catalytic reduction of NO by higher hydrocarbons , 2000 .
[162] H. Hamada,et al. Activity enhancement of SnO2-doped Ga2O3–Al2O3 catalysts by coexisting H2O for the selective reduction of NO with propene , 1999 .
[163] Guido Busca,et al. Chemical and mechanistic aspects of the selective catalytic reduction of NOx by ammonia over oxide catalysts: A review , 1998 .
[164] Michael A. Henderson,et al. Structural Sensitivity in the Dissociation of Water on TiO2 Single-Crystal Surfaces , 1996 .
[165] A. Bliek,et al. Inhibiting and deactivating effects of water on the selective catalytic reduction of Nitric Oxide with ammonia over MnOx/Al2O3 , 1996 .