Application of hopcalite catalyst for controlling carbon monoxide emission at cold-start emission conditions
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摘要
Carbon monoxide(CO) is a poisonous gas particularly to all leaving being present in the atmosphere.An estimate has shown that the vehicular exhaust contributes the largest source of CO pollution in developed countries.Due to the exponentially increasing number of automobile vehicles on roads,CO concentrations have reached an alarming level in urban areas.To control this vehicular exhaust pollution,the end-of-pipe-technology using catalytic converters is recommended.The catalysts operating efficiently in a catalytic converter are a challenging class of materials for applications in cold start of engines to maintain indoor air quality.In the cold start period,the catalytic converter was entirely inactive,because the catalytic converter had not been warmed up.The cold start phase is also depending upon the characteristics of vehicles and property of catalysts.The increasing cost of noble metals with the increasing number of vehicles motivates the investigation of material concepts to reduce the precious metal content in automotive catalysts or to find a substitute for noble metals.Hopcalite(CuMnOx) catalyst could work very well at the low temperature;thus,it can overcome the problem of cold-start emissions if used in a catalytic converter.Further,low cost,easy availability and advanced synthesis methods with stabilizer,promoter,etc.,advocates for the use of hopcalite as an auto exhaust purification catalyst.Although there are numerous research articles present on this topic until now,no review has been presented for demanding this issue.So there is a space in this area,and it has been made an attempt to seal this hole and progress the future scope for hopcalite catalyst for purification of exhaust gases by this review.
Carbon monoxide(CO) is a poisonous gas particularly to all leaving being present in the atmosphere.An estimate has shown that the vehicular exhaust contributes the largest source of CO pollution in developed countries.Due to the exponentially increasing number of automobile vehicles on roads,CO concentrations have reached an alarming level in urban areas.To control this vehicular exhaust pollution,the end-of-pipe-technology using catalytic converters is recommended.The catalysts operating efficiently in a catalytic converter are a challenging class of materials for applications in cold start of engines to maintain indoor air quality.In the cold start period,the catalytic converter was entirely inactive,because the catalytic converter had not been warmed up.The cold start phase is also depending upon the characteristics of vehicles and property of catalysts.The increasing cost of noble metals with the increasing number of vehicles motivates the investigation of material concepts to reduce the precious metal content in automotive catalysts or to find a substitute for noble metals.Hopcalite(CuMnOx) catalyst could work very well at the low temperature;thus,it can overcome the problem of cold-start emissions if used in a catalytic converter.Further,low cost,easy availability and advanced synthesis methods with stabilizer,promoter,etc.,advocates for the use of hopcalite as an auto exhaust purification catalyst.Although there are numerous research articles present on this topic until now,no review has been presented for demanding this issue.So there is a space in this area,and it has been made an attempt to seal this hole and progress the future scope for hopcalite catalyst for purification of exhaust gases by this review.
Carbon monoxide(CO) is a poisonous gas particularly to all leaving being present in the atmosphere.An estimate has shown that the vehicular exhaust contributes the largest source of CO pollution in developed countries.Due to the exponentially increasing number of automobile vehicles on roads,CO concentrations have reached an alarming level in urban areas.To control this vehicular exhaust pollution,the end-of-pipe-technology using catalytic converters is recommended.The catalysts operating efficiently in a catalytic converter are a challenging class of materials for applications in cold start of engines to maintain indoor air quality.In the cold start period,the catalytic converter was entirely inactive,because the catalytic converter had not been warmed up.The cold start phase is also depending upon the characteristics of vehicles and property of catalysts.The increasing cost of noble metals with the increasing number of vehicles motivates the investigation of material concepts to reduce the precious metal content in automotive catalysts or to find a substitute for noble metals.Hopcalite(CuMnOx) catalyst could work very well at the low temperature;thus,it can overcome the problem of cold-start emissions if used in a catalytic converter.Further,low cost,easy availability and advanced synthesis methods with stabilizer,promoter,etc.,advocates for the use of hopcalite as an auto exhaust purification catalyst.Although there are numerous research articles present on this topic until now,no review has been presented for demanding this issue.So there is a space in this area,and it has been made an attempt to seal this hole and progress the future scope for hopcalite catalyst for purification of exhaust gases by this review.
引文
Aguila,J.Chan,N.,Courtis,J.,1991.Proposed Regulations for California Phase 2 Reformulated Gasoline.Technical Support Document.California Air Resources Board,Sacramento.Air Improvement Resource,Inc.,2005.Examination of Temperature and RVP Effects on CO Emissions in EPA's Certification Database.Final Report CRC Project No.E-74a.Coordinating Research Council,Inc.,Alpharetta.Alfuso,S.,Aurlemma,M.,Police,G.,et al.,1993.The Effect of Methyl-Ester of Rapeseed Oil on Combustion and Emissions of Di-diesel Engines.Technical Paper 932801.SAE,Warrendale.Andre,J.M.,Joumard,R.,2005.Modeling of Cold Start Excess Emissions for Passenger Cars.INRETS Report No.LTE 0509.INRETS,Bron.Aspromonte,S.G.,Boix,A.V.,2019.Improving of cold-start and combustion emissions in lean NO conditions with active and selective AgAl mesoporous catalysts.Journal of Environmental Chemical Engineering 7(2),102995.Badr,O.,Probert,S.D.,1995.Carbon monoxide concentration in the earth's atmosphere.Fuel and Energy Abstracts 36(1),47.Ball,D.,1996.A Warm-up and Under Floor Converter Parametric Study.Technical Paper 932765.SAE,Warrendale.Bartley,G.J.J.,2001.Method for Reducing Cold-Start Hydrocarbon Emissions in a Gasoline,Natural Gas,or Propane Fueled Engine.US Patent 6244044.United States Patent and Trademark Office,Washington DC.Bartley,G.JJ.,2007.Sub-ambient cold-start emissions reduction using SwRI(?)POx catalyst technology.Topics of Catalysis 42(1-4),345-349.Benjamin,B.F.F.,Alphonse,P.,2016.Co-Mn-oxide spinel catalysts for GO and propane oxidation at mild temperature.Applied Catalysis B:Environmental 180,715—724.Bera,P.,Hegde,M.S., 2010.Recent advances in auto exhaust catalysis.Journal Indian Institute of Science 90,299-325.Bhasin,M.,Nagaki,D.,Koradi,P.,et al.,1993.Novel Catalyst System for Treating Exhaust Gases from InternalCombustion and Stationary Source Engines.Technical Paper930254.SAE,Warrendale.
Bhaskar,K.,Nagarajan,G.,Sampath,S.,2010.Experimental investigation of cold start emissions using electrically heated catalysts in a spark ignition engine.International Journal of Automot:ive and Mechanical Engineering 2(1),105—118.
Biemelt,T., Wegner,K.,Trichert,J.,et al.,2015.Hopcalite nanoparticle catalysts with high water vapor stability for catalytic oxidation of carbon monoxide.Applied Catalysis B:Environmental 184,208—215.
Blondeau,J., Mertens,J.,2019.Impact of intermittent renewable energy production on specific CO_2 and NOx emissions from large scale gas-fired combined cycles.Journal of Cleaner Production 221,261-270.
Borland,M.,Zhao,F.,2002.Application of secondary air injection for simultaneously reducing converter-in emissions and improving catalyst light-off performance.In:SAE Powertrain&Fluid Conference&Exhibition,Washington DC,2002.
Burk,P.L.,Hochmuth,J.K.,Anderson,D.R.,et al.,1995a.Cold start hydrocarbon emissions control via admixing three way conversion catalysts with heat exchange and hydrocarbon adsorption phenomena.Studies in Surface Science and Catalysis 96,919-930.
Burk,P.L.,Hochmuth,J.K.,Anderson,D.R.,et al.,1995b.Cold Start Hydrocarbon Emissions Control.Technical Paper 950410.SAE,Warrendale.
Burk,N.R.,Trimm,D.L.Howe,R.F.,2003.The effect of silica:alumina ratio and hydrothermal ageing on the adsorption characteristics of BEA zeolites for cold start emission control.Applied Catalysis B:Environmental 46(1),97104.
Cai,L.,Guo,Y.,Lu,A.,et al.,2012.The choice of precipitant and precursor in the co-precipitation synthesis of copper manganese oxide for maximizing carbon monoxide oxidation.Journal of Molecular Catalysis A:Chemical 360,35-41.
Chan,S.H.,Zhu,J.,1999.The Significance of High Value of Ignition Retard Control on the Catalyst Light-Off.Technical Paper962077.SAE,Warrendale.
Chen,Y.,Ma,J.,Han,B.,et al.,2018.Emissions of automobiles fueled with alternative fuels based on engine technology:a review.Journal of Traffic and Transportation Engineering(English Edition)5(4),318-334.
Chhatwal,G.R.,Mehra,M.C.,Sataka,M.,et al.,1975.In Environmental Air Pollution and its Control.Anmol Publications,New Delhi.
Choi,K.,Lee,D.,Kim,H.,et al.,2016.Reaction characteristics of precious-metal-free ternary Mn-Gu-M(M=Ce,Co,Cr and Fe)oxide catalysts for low-temperature CO oxidation.Industrial and Engineering Chemistry Research 55(16),4443-4450.
Cholakov,G.S.,2010.Control of exhaust emissions from internal combustion engine vehicles.Pollution Control Technologies3,1-8.
Cholakov,G.S.,2018.Catalytic converters and other emission control devices.Pollution Control Technologies 3,11—18.
Clarke,T.J.,Davies,T.E.,Kondrat,S.A.,et al.,2015.Mechanochemical synthesis of copper manganese oxide for the ambient temperature oxidation of carbon monoxide.Applied catalysis B:Environmental 165,222—231.
Cole,K.J.,Carley,A.F.,Crudace,M.J.,et al.,2010.Copper manganese oxide catalysts modified by gold deposition:the influence on activity for ambient temperature carbon monoxide oxidation.Catalysis Letters 138(3),143—147.
Comotti,M.,Li,W.,Spliethoff,B.,et al.,2006.Support effect in high activity gold catalysts for CO oxidation.Journal of American Chemical Society 128(3),917—924.
Cortie,M.B.,Vander,L.E.,2002.Catalytic gold nano-particles.Materials Forum 26,1-14.
Cullen,M.J.,Rollinger,J., Kapolnek,M., et al., 2007.Cold Start Emission Reduction Monitoring System and Meilthod.US2007/0283682 A1.United States Patent and Trademark Office,Washington DC.
Czaplewski,K.F.,Reitz,T.L.,Kim,Y.J.,et al.,2002.Onedimensional zeolites as hydrocarbon traps.Microporous and Mesoporous Materials 56(1),55—64.
Davis,R.J.,Kung,M.C.,2007.Understanding Au-catalyzed lowtemperature CO oxidation.In:AlChE Annual Meeting,Salt Lake City,2007.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2017.Study of hopcalite(CuMnO_x)catalysts prepared through a novel route for the oxidation of carbon monoxide at low temperature.Bulletin of Chemical Reaction Engineering&Catalysis 12(3),393-407.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2018.Effect of various metal oxides phases present in CuMnO_x catalyst for selective CO oxidation.Materials Discovery 12,3—71.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2019a.Ambient temperature complete oxidation of carbon monoxide using hopcalite catalysts for fire escape mask applications.Advanced Composites and Hybrid Materials 2(6),1—19.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2019b.Synthesis of the silver promoted CuMnO_x catalyst for ambient temperature oxidation of carbon monoxides.Journal of Science:Advanced Materials and Devices 4(1),47-56.
Dey,S.,Dhal,G.C.,Prasad,R.,et al.,2016.Effect of nitrate metal(Ce,Cu,Mn and Co)precursors for the total oxidation of carbon monoxide.Resource-Efficient Technologies 3(3),293-302.
Dhanalakshmi,A.,Suresh,M.,2018.Experimental investigation of emission control using Ag catalytic converter in a four stoke diesel engine.International Journal of Mechanical Engineering and Technology 9(13),199—202.
E,J.,Liu,G.,Zhang,Z.,et al.,2019.Effect analysis on cold starting performance enhancement of a diesel engine fueled with biodiesel fuel based on an improved thermodynamic model.Applied Energy 243,321-335.
Elangovan,S.P.,Ogura,M.,Davis,M.E.,et al.,2004.SSZ-33:a promising material for use as a hydrocarbon trap.Journal of Physical Chemistry B 108(35),13059-13061.
Elangovan,S.P.,Ogura,M.,Zhang,Y.,et al.,2005.Silicoalumino phosphate molecular sieves as a hydrocarbon trap.Applied Catalysis B:Environmental 57(1),31—36.
Elmhamdi,A., Pascual,L.,Nahdi,K.,et al.,2017.Structure/redox/activity relationships in CeO_2/CuMn_2O_4 CO-PROX catalysts.Applied Catalysis B:Environmental 217,1—11.
Faiz,A.,Weaver,C.S.,Walsh,M.P.,1996.Air Pollution from Motor Vehicles,Standards and Technologies for Controlling Emissions.The World Bank Reconstruction and Development,Washington DC.
Favez,J.Y.,Weilenmann,M.,Stilli,J., 2009.Cold start extra emissions as a function of engine stop time:evolution over the last 10 years.Atmospheric Environment 43(5),996—1007.
Gao,J.,Jia,C.,Zhang,L.,et al.,2016.Tuning chemical bonding of MnO_2 through transition-metal doping for enhanced CO oxidation.Journal of Catalysis 341,82-90.
Gao,J.,Tian,G.,Sorniotti,A.,et al.,2019.Review of thermal management of catalytic converters to decrease engine emissions during cold start and warm up.Applied Thermal Engineering 147,177-187.
Giakoumis,E.G.,Dimaratos,A.M.,Rakopoulos,C.D.,et al.,2017.Combustion instability during starting of turbocharged diesel engine including biofuel effects.Journal of Energy Engineering 143(2),04016047.
Gottberg,I.,Rydquist,J.,Backlund,J.,et al.,1986.New Potential Exhaust Gas after Treatment Technologies for"Clean Car"Legislation.Technical Paper 910840.SAE,Warrendale.
Hamedi,M.R.,Doustdara,O.,Tsolakis,A.,et al.,2019.Thermal energy storage system for efficient diesel exhaust after treatment at low temperatures.Applied Energy 235,874—887.
Haruta,M.,Sano,H.,1981.Catalytic combustion of hydrogen I—its role in hydrogen utilization system and screening of catalyst materials.International Journal of Hydrogen Energy6(6),601-608.
Haruta,M.,Yamada,N.,Kobayashi,T.,et al.,1989.Gold catalysts prepared by co-precipitation for low-temperature oxidation of hydrogen and of carbon monoxide.Journal of Catalysis 115(2),301-309.
Hasegawa,Y.,Maki,R.,Sano,M.,et al.,2009.Preferential oxidation of CO on copper-containing manganese oxides.Applied Catalysis A:General 371(1-2),67—72.
Heck,R.M.,Farrauto,R.J.,2001.Automobile exhaust catalysts.Applied Catalysis A:General 221(1—2),443-457.
Heck,R.M.,Hu,Z.,Smaling,R.,et al.(1995.Close Coupled Catalyst System Design and ULEV Performance after 1050℃Aging.Technical Paper 952415.SAE,Warrendale.
Hedinger,R.,Elbert,P.,Onder,C.,2017.Optimal cold-start control of a gasoline engine.Energies 10(10),1—17,1548.
Heimrich,M.J.,Smith,L.R.,Kitowski,J.,1992.Cold-start Hydrocarbon Collection for Advanced Exhaust Emission Control.Technical Paper 920847.SAE,Warrendale.
Hey,wood,J.B.,1997.Motor vehicle emissions control:past achievements,future prospects.In:Handbook of Air Pollution Form Internal Combustion Engines.Academic Dress,Salt Lake City,pp.3-23.
Hochmuth,J.K.,Burk,P.L.,Tolentino,C.,et al.,1993.Hydrocarbon Traps for Controlling Cold Start Emissions.Technical Paper930739.SAE,Warrendale.
Hoshyar,N.,Irankhak,A.,Jafari,M.,2015.Copper catalysts supported on CeMn02 for CO oxidation in hydrogen rich gas streams.Iranian Journal of Chemical Engineering 12(3),3-14.
Hu,T.,Wei,Y.,Liu,S.,et al.,2007.Improvement of spark-ignition(SI)engine combustion and emission during cold-start,fueled with methanol/gasoline 1820 blends.Energy Fuels 21(1),171-178.
Huang,T.,Tsai,D., 2003.CO oxidation behavior of copper and copper oxides.Catalysis Letters 87(3-4),173—178.
Hutchings,G.J.,Mirzaei,A.A.,Joyner,R.W.,et al.,1996.Ambient temperature CO oxidation using copper manganese oxide catalysts prepared by co-precipitation:effect of ageing on catalyst performance.Catalysis Letters42(1-2),21-24.
Hutchings,G.J.,Mirzaei,A.A.,Joynerb,R.W.,et al.,1998.Effect of preparation conditions on the catalytic performance of copper manganese oxide catalysts for CO oxidation.Applied Catalysis A:General 166(1),143-152.
Iliyas,A.,2008.One-dimensional Molecular Sieves for Hydrocarbon Gold-Start Emission Control(PhD thesis).The University of New Brunswick,Frederiction.
Innovative Transport Solutions(iTrans)Pvt.Ltd.,2009.Final Report for International Council for Clean Transportation(ICCT)&the Institute for Transport and Development Policy(ITDP).TBIU,New Delhi.
International Council on Clean Transportation(ICCT),2016.India Bharat Stage VI Emission Standards.Policy Update.ICCT,New Delhi.
Iodice,P.,Senatore,A.,2012.Analysis of a Scooter Emission Behavior in Cold and Hot Conditions:Modelling and Experimental Investigations.Technical Paper 2012-01-0881.SAE,Warrendale.
Iodice,P.,Senatore,A. 2013.Road transport emission inventory in a regional area by using experimental two-wheelers emission factors.In:World Congress on Engineering,London,2013.
Iodice,P.,Senatore,A.,2015.Appraisal of pollutant emissions and air quality state in a critical Italian region:methods and results.Environmental Progress&Sustainable Energy 34(5),1497-1505.
Iodice,P.,Senatore,A.,2016.A numerical-experimental approach to assess emission performance of new generation engines during the cold transient.International Journal of Automotive and Mechanical Engineering 13(3),3599-3612.
Iodice,P.,Senatore,A.,Langella,G.,et al.,2016.Effect of ethanol—gasoline blends on CO and HC emissions in last generation SI engines within the cold-start transient:an experimental investigation.Applied Energy 179,182-190.
Ismaila,S.O.,Bolaji,B.O.,Adetunji,O.R.,et al.,2013.On vehicular emissions of petrol and diesel engines.International Journal of Engineering 1584,178-180.
Jones,C.,Cole,K.J.,Taylor,S.H.,et al.,2009.Copper manganese oxide catalysts for ambient temperature carbon monoxide oxidation:effect of calcination on activity.Molecular Catalysis A:Chemical 305(1-2),121-124.
Jones,C.,Taylor,S.H.,Burrows,A.,et al.,2008.Cobalt promoted copper manganese oxide catalysts for ambient temperature carbon monoxide oxidation.Chemical Communication 1707,1-7.
Kam,E.K.T.,Hughes,R.,1979.The effect of catalyst fouling on the performance of adiabatic packed-bed reactors-a theoretical study.Chemical Engineering Journal 18(1),93-102.
Kamrani,E.,2008.Adaptive fuzzy control for air-fuel ratio of automobile spark ignition engine.World Journal of Engineering and Technology 2(12),196-204.
Kanada,Y.,Hayashi,M.,Akaki,M.,et al.,1996.Hydrogen Added After-Burner System.Technical Paper 960346.SAE,Warrendale.
Kandylas,I.P.,Stamatelos,A.M.,1999.Engines exhaust system design based on heat transfer computation.Energy Conversion&Management 40(10),1057—1072.
Kireev,A.S.,Mukhin,V.M.,Kireev,S.G.,et al.,2009.Preparation and properties of modified hopcalite.Russian Journal of Applied Chemistry 82(1),169-171.
Kishi,N.,Hashimoto,H.,Fujimori,K.,et al.,1998.Development of the Ultra Low Heat Capacity and Highly Insulating(ULOC)Exhaust Manifold for ULEV.Technical Paper 980937.SAE,Warrendale.
Kondrat,S.A.,Davies,T.E.,Zu,Z.,et al.,2011.The effect of heat treatment on phase formation of copper manganese oxide:influence on catalytic activity for ambient temperature carbon monoxide oxidation.Journal of Catalysis 281(2),279-289.
Kramer,M.,Schmidt,T.,Stowe,K., et al.,2006.Structural and catalytic aspects of sol-gel derived copper manganese oxides as low-temperature CO oxidation catalyst.Applied Catalysis A:General 302,257-263.
Krishna,S.M.,Salam,P.A.,Tongroon,M.,et al.,2019.Performance and emission assessment of optimally blended biodieseldiesel-ethanol in diesel engine generator.Applied Thermal Engineering 155,525—533.
Lafyatis,D.S.,Ansell,G.P.,Bennett,S.C.,et al.,1998.Ambient temperature light-off for automobile emission control.Applied Catalysis B:Environmental 18(1—2),123—135.
Laing,P.,1994.Development of an Alternator-Powered Electrically-Heated Catalyst System.Technical Paper 941042.SAE,Warrendale.
Layla,A.,Azim,M.,Ali,K.A.,et al.,2008.Effects of excess cobalt oxide nanocrystallites on LaCo03 catalyst on lowering the light off temperature of CO and hydrocarbons oxidation.Iranian Journal of Chemical Engineering 27,71—77.
Lee,D.,2010.Effects of Secondary Air Injection during Cold Start of SI Engines(PhD thesis).Massachusetts Institute of Technology,Boston.
Li,H.,Andrews,G.E.,Savvidis,D.,et al.,2008.Study of thermal characteristics and emissions during cold start using an onboard measuring method for modern SI car real world urban driving.SAE International Journal of Engines 1,804—819.
Li,L.,Wang,S.,Wang,G.,et al.,2019.Effect of clamping stress on cold start performance of PEMFC.Energy Procedia 158,1744-1749.
Li,M.,Wang,D.,Shi,X.,et al.,2007.Kinetics of catalytic oxidation of CO over copper-manganese oxide catalyst.Separation and Purification Technology 57(1),147—151.
Libardi,S.H.,Skibsted,L.H.,Cardoso,D.R.,2014.Oxidation of carbon monoxide by perferrylmyoglobin.Journal of Agricultural and Food Chemistry 62(8),1950-1955.
Lisnyak,V.V.,Safonova,V.V.,Ischenko,E.V.,et al.,2012.Preparation and activity of Pt(Pd)/WP207 catalysts for H_2oxidation.Research Journal of Chemical Sciences 2(6),50-54.
Liu,X.,Wei,X.,2008.Hydrothermally Stable Ag-Zeolite Traps for Small Olefin Hydrocarbon Molecules.US Patent 20080253950.United States Patent and Trademarks Office,Washington DC.
Lopez-Perez,E.,Hermosilla,T.,Garot-Sierra,J.M.,et al.,2019.Spatial determination of traffic CO emissions within street canyons using inverse modeling.Atmospheric Pollution Research 1—8,https://doi.org/10.1016/j.apr.2019.01.019.
Lu,G.Y.,Zhang,Z.G.,2010.Close Coupled Catalyst for Purification of Exhaust Gas and the Preparation Thereof.US Patent20100048383.United States Patent and Trademark Office,Washington DC.
Ludykar,D.,Westerholm,R.,Almen,J.,1999.Cold start emissions at+22,—7 and—20℃ambient temperatures from a three-way catalyst(TWC)car:regulated and unregulated exhaust components.The Science of Total Environment 235(1—3),65-69.
Ma,T.Collings,N.,Hands,T.,1992.Exhaust Gas Ignition(EGI)—a New Concept for Rapid Light-off of Automotive Exhaust Catalyst.Technical Paper 920400.SAE,Warrendale.
Min,B.K.,Friend,C.M.,2007.Heterogeneous gold-based catalysis for green chemistry:low-temperature CO oxidation and propane oxidation.Chemical Reviews 107(6),2709-2724.
Mirzaei,A.A.,Shaterian,R.H.,Habibi,M.,et al., 2003.Characterization of copper-manganese oxide catalysts:effect of precipitate ageing upon the structure and morphology of precursors and catalysts.Applied Catalysis A:General 253(2),499-508.
Mirzaei,A.A.,Shaterian,H.R.,Joyner,R.W.,et al.,2013.Ambient temperature carbon monoxide oxidation using copper manganese oxide catalysts:effect of residual Na+acting as catalyst poison.Catalysis Communication 4,17-20.
Morgan,K.,Cole,K.J.,Goguet,A., et al.,2010.TAP studies of CO oxidation over GuMnO_x and Au/CuMnO_x catalysts.Journal of Catalysis 276,38-48.
Njagi,E.C.,Chen,C.,Genuine,H.,et al.,2010.Total oxidation of CO at ambient temperature using copper manganese oxide catalysts prepared by a redox method.Applied Catalysis B:Environmental 99(1-2),103-110.
Njagi,E.C.,Genuino,H.C.,Kingondu,C.K.,et al.,2011.Preferential oxidation of CO in H_2 rich feeds over mesoporous copper manganese oxide synthesized by a redox method.International Journal of Hydrogen Energy36(11),6768-6779.
Oser,P.,Mueller,E.,Hartel,G.,et al.,1994.Novel Emission Technologies with Emphasis on Catalyst Cold Start Improvements Status Report on VW-Pierburg Burnerl Catalyst Systems.Technical Paper 940474.SAE,Warrendale.
Paldey,S.,Gedevanishvili,S.,Zhang,W.,et al.,2005.Evaluation of a spinel based pigment systems as a CO oxidation catalyst.Applied Catalysis B:Environmental 56(3),241-250.
Patil,M.D.,Hertl,W.,Williams,J.L.,et al.,1996.In-line Hydrocarbon Adsorber System for ULEV.Technical Paper960348.SAE,Warrendale.
Patil,M.D.,Peng,Y.L.,Morse,K.E.,1998.Airless In-Line Adsorber System for Reducing Cold Start HC Emissions.Technical Paper 980419.SAE,Warrendale.
Pattrick,G.,Vander Lingen,E.,Corti,C.W.,et al.,2004.The potential for use of gold in automotive pollution control technologies:a short review.Topics in Catalysis 30(1—4),273-279.
Pillai,U.R.,Deevi,S.,2006.Room temperature oxidation of carbon monoxide over copper oxide catalyst.Applied Catalysis B:Environmental 64(1-2),146—151.
Puertolas,B.,Navlani-Garcia,M.,Lopez,J.M.,et al.,2012.Molecular simulation design of a multisite solid for the abatement of cold start emissions.Chemical Communications 48(52),6571-6573.
Pulkrabek,W.W.,2004.Engineering Fundamentals of the Internal Combustion Engine.Pearson Prentice Hall,Upper Saddle River.
Qian,K.,Qian,Z.,Hua,Q.,et al.,2013.Structure activity relationship of CuO/MnO_2 catalysts in CO oxidation.Applied Surface Science 273,357-363.
Quarles,J.,1974.Control of air pollution from new motor vehicles and new motor vehicle engines.Federal Register of United States 39(204),38250-38271.
Rajvanshi,A.K.,2002.Electric and improved cycle rickshaw as a sustainable transport system for India.Current Science 83(6),1-6.
Rani,R.,Prasad,R.,2014.Studies of carbon monoxide oxidation at ambient conditions.Recent Research in Science and Technology 6,89—92.
Raphulu,M.C.,2004.Catalytic Oxidation of Carbon Monoxide and Methane with Gold Based Catalysts(PhD thesis).University of the Witwatersrand,Johannesburg.
Roberts,A.,Brooks,R.,Shipway,P.,2014.Internal combustion engine cold-start efficiency:a review of the problem,causes and potential solutions.Energy Conversion and Management82,327-350.
Romero-Sarria,F.,Plata,J.J.,Laguna,O.H.,et al.,2014.Surface oxygen vacancies in gold based catalysts for CO oxidation.RSC Advances 4(25),13145-13152.
Roozbehani,B.,Houshmand,D.,Badakhshan,A.,2013.Thermal and catalytic degradation of polystyrene with a novel catalyst.Science International 25(4),819.
Royer,S.,Duprez,D.,2011.Catalytic oxidation of carbon monoxide over transition metal oxides.Chemcatchem 3,24-65.
Russ,S.,Thiel,M.,Lavoie,G.,1999.SI Engine Operation with Retarded Ignition:Part 2—HC Emissions and Oxidation.Technical Paper 993507.SAE,Warrendale.
Ryou,Y.S.,Lee,J.,Kim,Y.,et al.,2019.Effect of reduction treatments(H_2 vs.CO)on the NO adsorption ability and the physicochemical properties of Pd/SSZ-13 passive NOx adsorber for cold start application.Applied Catalysis A:General 569,28—34.
Santoso,H.G.,Ament,F.,2010.Cold Start Emission Strategy for Hybrid Vehicles.US 7778767.United States Patent and Trademark Office,Washington DC.
Sendilvelan,S.,Bhaskar,K.,2016.Electrically heated transition metal oxide catalyst for cold start emission reduction from gasoline engine.Indian Journal of Environmental Protection36(12),986-992.
Sendilvelan,S., Sassykova,L.,2019.Chemically heated catalytic converter design options and performance using heated metal oxides.Journal of Chemical Technology and Metallurgy 54(3),571—577.
Shi,L.,Hu,Z.,Deng,G.,et al.,2015.Carbon monoxide oxidation on copper manganese oxides prepared by selective etching with ammonia.Chinese Journal of Catalysis 36(11),1920-1927.
Shimasaki,Y.,Kato,H.,Abe,F.,et al.,1997.Development of Extruded Electrically Heated Catalyst System for ULEV Standards.Technical Paper 971031.SAE,Warrendale.
Sierra Research,Inc,2002.Review of CO Compliance Status in Selected Western Areas.SR02-09-04.Sierra Research,Inc.,Mountain View.
Sierra Research,Inc,2003.Review of Current and Future CO Emissions from On-Road Vehicles in Selected Western Areas.SR03-01-01.Sierra Research,Inc.,Mountain View.
Singh,P.,Prasad,R.,2014.Catalytic abatement of cold start vehicular CO emissions.Catalysis Industry 6(2),122-127.
Solsona,B.,Hutchings,G.J.,Garcia,T.,et al.,2004.Improvement of the catalytic performance of CuMnO_x catalysts for CO oxidation by the addition of Au.New Journal of Chemistry28,708-711.
Sothea,K.,Oanh,N.T.K.,2019.Characterization of emissions from diesel backup generators in Cambodia.Atmospheric Pollution Research 10,345—354.
Summers,J.,Skowron,J.,Miller,M.,1993.Use of Light-off Catalysts to Meet the California LEV/ULEV Standards.Technical Paper 930386.SAE,Warrendale.
Sun,J.,Sivashankar,N.,1998.Issues in cold start emission control for automotive IC engines.In:The American Control Conference,Philadelphia,1998.
Takei,Y.,Hirohiko,H.,Okada,M.,et al.,1993.Effect of Gasoline Components on Exhaust Hydrocarbon Components.Technical Paper 932670.SAE,Warrendale.
Tanaka,Y.,Utaka,T.,Kikuchi,R.,et al.,2003.Water gas shift reaction for the reformed fuels over Cu/MnO catalysts prepared via spinel-type oxide.Journal of Catalysis 215(2),271-278.
Tang,Z.R.,Kondrat,S.A.,Dickinson,C.,et al.,2011.Synthesis of high surface area CuMn_2O_4 by supercritical anti-solvent precipitation for the oxidation of CO at ambient temperature.Catalysis Science&Technology 1(5),740—746.
Taylor,S.H.,Hutchings,G.J.,Mirzaei,A.A.,1999.Copper zinc oxide catalysts for ambient temperature carbon monoxide oxidation.Chemical Communications 15,1373—1374.
Tingvall,B.,Pettersson,E.,2009.Demonstration of Multi Gas Exhaust Measurements during Cold Start Conditions.Lulea University of Technology,Lulea.
Ueno,M.,Akazaki,S.,Yasui,Y.,et al.,2000.A Quick Warm-Up System during Engine Start-Up Period Using Adaptive Control of Intake Air and Ignition Timing.Technical Paper000551.SAE,Warrendale.
Vasic,A.M.,Weilenmann,M., 2006.Comparison of real-world emissions from two wheelers and passenger cars.Environmental Science&Technology 40(1),149-154.
Veprek,S.,Cocke,D.L.,Kehl,S.,et al., 1986.Mechanism of the deactivation of hopcalite catalysts studied by XPS,ES and other techniques.Journal of Catalysis 100(1),250—263.
Wang,W.,Lahti,J.L.,Gillanders,C.A.,et al.,2009.Method for Onboard Diagnosis of Cold Start Emissions Reduction Control Strategy.US 7630826.United States Patent and Trademark Office,Washington DC.
Weilenmann,M.,Soltic,P.,Saxer,C.,et al.,2005.Regulated and nonregulated diesel and gasoline cold-start emissions at different temperatures.Atmospheric Environment 39(13),2433-2441.
Williams,J.L.,Patil,M.D.,Hertl,W.,1996.By-pass Hydrocarbon Adsorber System for ULEV.Technical Paper 960343.SAE,Warrendale.
Yusuf,A.A.,Inambao,F.L.,2019.Effect of cold start emissions from gasoline-fueled engines of light-duty vehicles at low and high ambient temperatures:recent trends.Case Studies in Thermal Engineering 14,100417.
Zaki,M.I.,Hasan,M.A.,Pasupulety,L.,2009.Influence of CuOx additives on CO oxidation activity and related surface and bulk behaviors of Mn_2O_3,Cr_2O_3 and W03 catalysts.Applied Catalysis A:General 198,247—259.
Zhao,F.,Gong,M.,Zhang,G.,et al.,2015.Effect of the loading content of GuO on the activity and structure of CuO/Ce-Mn-O catalysts for CO oxidation.Journal of Rare Earths 33(6),604-610.
Zhou,L.,Hua,J.,Wei,H.,et al.,2019.An experimental investigation on low load combustion stability and coldfiring capacity of a gasoline compression ignition engine.Engineering 5(3),558-567.
Zhou,Y.,Wang,Z.,Liu,C.,2014.Perspective on CO oxidation over Pd-based catalysts.Catalysis Science and Technology 1,69—81.
Zhu,M.,Xie,X.,Wu,K.,et al.,2019.Experimental investigation of the effect of membrane water content on PEM fuel cell cold start.Energy Procedia 158,1724—1729.
Bhaskar,K.,Nagarajan,G.,Sampath,S.,2010.Experimental investigation of cold start emissions using electrically heated catalysts in a spark ignition engine.International Journal of Automot:ive and Mechanical Engineering 2(1),105—118.
Biemelt,T., Wegner,K.,Trichert,J.,et al.,2015.Hopcalite nanoparticle catalysts with high water vapor stability for catalytic oxidation of carbon monoxide.Applied Catalysis B:Environmental 184,208—215.
Blondeau,J., Mertens,J.,2019.Impact of intermittent renewable energy production on specific CO_2 and NOx emissions from large scale gas-fired combined cycles.Journal of Cleaner Production 221,261-270.
Borland,M.,Zhao,F.,2002.Application of secondary air injection for simultaneously reducing converter-in emissions and improving catalyst light-off performance.In:SAE Powertrain&Fluid Conference&Exhibition,Washington DC,2002.
Burk,P.L.,Hochmuth,J.K.,Anderson,D.R.,et al.,1995a.Cold start hydrocarbon emissions control via admixing three way conversion catalysts with heat exchange and hydrocarbon adsorption phenomena.Studies in Surface Science and Catalysis 96,919-930.
Burk,P.L.,Hochmuth,J.K.,Anderson,D.R.,et al.,1995b.Cold Start Hydrocarbon Emissions Control.Technical Paper 950410.SAE,Warrendale.
Burk,N.R.,Trimm,D.L.Howe,R.F.,2003.The effect of silica:alumina ratio and hydrothermal ageing on the adsorption characteristics of BEA zeolites for cold start emission control.Applied Catalysis B:Environmental 46(1),97104.
Cai,L.,Guo,Y.,Lu,A.,et al.,2012.The choice of precipitant and precursor in the co-precipitation synthesis of copper manganese oxide for maximizing carbon monoxide oxidation.Journal of Molecular Catalysis A:Chemical 360,35-41.
Chan,S.H.,Zhu,J.,1999.The Significance of High Value of Ignition Retard Control on the Catalyst Light-Off.Technical Paper962077.SAE,Warrendale.
Chen,Y.,Ma,J.,Han,B.,et al.,2018.Emissions of automobiles fueled with alternative fuels based on engine technology:a review.Journal of Traffic and Transportation Engineering(English Edition)5(4),318-334.
Chhatwal,G.R.,Mehra,M.C.,Sataka,M.,et al.,1975.In Environmental Air Pollution and its Control.Anmol Publications,New Delhi.
Choi,K.,Lee,D.,Kim,H.,et al.,2016.Reaction characteristics of precious-metal-free ternary Mn-Gu-M(M=Ce,Co,Cr and Fe)oxide catalysts for low-temperature CO oxidation.Industrial and Engineering Chemistry Research 55(16),4443-4450.
Cholakov,G.S.,2010.Control of exhaust emissions from internal combustion engine vehicles.Pollution Control Technologies3,1-8.
Cholakov,G.S.,2018.Catalytic converters and other emission control devices.Pollution Control Technologies 3,11—18.
Clarke,T.J.,Davies,T.E.,Kondrat,S.A.,et al.,2015.Mechanochemical synthesis of copper manganese oxide for the ambient temperature oxidation of carbon monoxide.Applied catalysis B:Environmental 165,222—231.
Cole,K.J.,Carley,A.F.,Crudace,M.J.,et al.,2010.Copper manganese oxide catalysts modified by gold deposition:the influence on activity for ambient temperature carbon monoxide oxidation.Catalysis Letters 138(3),143—147.
Comotti,M.,Li,W.,Spliethoff,B.,et al.,2006.Support effect in high activity gold catalysts for CO oxidation.Journal of American Chemical Society 128(3),917—924.
Cortie,M.B.,Vander,L.E.,2002.Catalytic gold nano-particles.Materials Forum 26,1-14.
Cullen,M.J.,Rollinger,J., Kapolnek,M., et al., 2007.Cold Start Emission Reduction Monitoring System and Meilthod.US2007/0283682 A1.United States Patent and Trademark Office,Washington DC.
Czaplewski,K.F.,Reitz,T.L.,Kim,Y.J.,et al.,2002.Onedimensional zeolites as hydrocarbon traps.Microporous and Mesoporous Materials 56(1),55—64.
Davis,R.J.,Kung,M.C.,2007.Understanding Au-catalyzed lowtemperature CO oxidation.In:AlChE Annual Meeting,Salt Lake City,2007.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2017.Study of hopcalite(CuMnO_x)catalysts prepared through a novel route for the oxidation of carbon monoxide at low temperature.Bulletin of Chemical Reaction Engineering&Catalysis 12(3),393-407.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2018.Effect of various metal oxides phases present in CuMnO_x catalyst for selective CO oxidation.Materials Discovery 12,3—71.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2019a.Ambient temperature complete oxidation of carbon monoxide using hopcalite catalysts for fire escape mask applications.Advanced Composites and Hybrid Materials 2(6),1—19.
Dey,S.,Dhal,G.C.,Mohan,D.,et al.,2019b.Synthesis of the silver promoted CuMnO_x catalyst for ambient temperature oxidation of carbon monoxides.Journal of Science:Advanced Materials and Devices 4(1),47-56.
Dey,S.,Dhal,G.C.,Prasad,R.,et al.,2016.Effect of nitrate metal(Ce,Cu,Mn and Co)precursors for the total oxidation of carbon monoxide.Resource-Efficient Technologies 3(3),293-302.
Dhanalakshmi,A.,Suresh,M.,2018.Experimental investigation of emission control using Ag catalytic converter in a four stoke diesel engine.International Journal of Mechanical Engineering and Technology 9(13),199—202.
E,J.,Liu,G.,Zhang,Z.,et al.,2019.Effect analysis on cold starting performance enhancement of a diesel engine fueled with biodiesel fuel based on an improved thermodynamic model.Applied Energy 243,321-335.
Elangovan,S.P.,Ogura,M.,Davis,M.E.,et al.,2004.SSZ-33:a promising material for use as a hydrocarbon trap.Journal of Physical Chemistry B 108(35),13059-13061.
Elangovan,S.P.,Ogura,M.,Zhang,Y.,et al.,2005.Silicoalumino phosphate molecular sieves as a hydrocarbon trap.Applied Catalysis B:Environmental 57(1),31—36.
Elmhamdi,A., Pascual,L.,Nahdi,K.,et al.,2017.Structure/redox/activity relationships in CeO_2/CuMn_2O_4 CO-PROX catalysts.Applied Catalysis B:Environmental 217,1—11.
Faiz,A.,Weaver,C.S.,Walsh,M.P.,1996.Air Pollution from Motor Vehicles,Standards and Technologies for Controlling Emissions.The World Bank Reconstruction and Development,Washington DC.
Favez,J.Y.,Weilenmann,M.,Stilli,J., 2009.Cold start extra emissions as a function of engine stop time:evolution over the last 10 years.Atmospheric Environment 43(5),996—1007.
Gao,J.,Jia,C.,Zhang,L.,et al.,2016.Tuning chemical bonding of MnO_2 through transition-metal doping for enhanced CO oxidation.Journal of Catalysis 341,82-90.
Gao,J.,Tian,G.,Sorniotti,A.,et al.,2019.Review of thermal management of catalytic converters to decrease engine emissions during cold start and warm up.Applied Thermal Engineering 147,177-187.
Giakoumis,E.G.,Dimaratos,A.M.,Rakopoulos,C.D.,et al.,2017.Combustion instability during starting of turbocharged diesel engine including biofuel effects.Journal of Energy Engineering 143(2),04016047.
Gottberg,I.,Rydquist,J.,Backlund,J.,et al.,1986.New Potential Exhaust Gas after Treatment Technologies for"Clean Car"Legislation.Technical Paper 910840.SAE,Warrendale.
Hamedi,M.R.,Doustdara,O.,Tsolakis,A.,et al.,2019.Thermal energy storage system for efficient diesel exhaust after treatment at low temperatures.Applied Energy 235,874—887.
Haruta,M.,Sano,H.,1981.Catalytic combustion of hydrogen I—its role in hydrogen utilization system and screening of catalyst materials.International Journal of Hydrogen Energy6(6),601-608.
Haruta,M.,Yamada,N.,Kobayashi,T.,et al.,1989.Gold catalysts prepared by co-precipitation for low-temperature oxidation of hydrogen and of carbon monoxide.Journal of Catalysis 115(2),301-309.
Hasegawa,Y.,Maki,R.,Sano,M.,et al.,2009.Preferential oxidation of CO on copper-containing manganese oxides.Applied Catalysis A:General 371(1-2),67—72.
Heck,R.M.,Farrauto,R.J.,2001.Automobile exhaust catalysts.Applied Catalysis A:General 221(1—2),443-457.
Heck,R.M.,Hu,Z.,Smaling,R.,et al.(1995.Close Coupled Catalyst System Design and ULEV Performance after 1050℃Aging.Technical Paper 952415.SAE,Warrendale.
Hedinger,R.,Elbert,P.,Onder,C.,2017.Optimal cold-start control of a gasoline engine.Energies 10(10),1—17,1548.
Heimrich,M.J.,Smith,L.R.,Kitowski,J.,1992.Cold-start Hydrocarbon Collection for Advanced Exhaust Emission Control.Technical Paper 920847.SAE,Warrendale.
Hey,wood,J.B.,1997.Motor vehicle emissions control:past achievements,future prospects.In:Handbook of Air Pollution Form Internal Combustion Engines.Academic Dress,Salt Lake City,pp.3-23.
Hochmuth,J.K.,Burk,P.L.,Tolentino,C.,et al.,1993.Hydrocarbon Traps for Controlling Cold Start Emissions.Technical Paper930739.SAE,Warrendale.
Hoshyar,N.,Irankhak,A.,Jafari,M.,2015.Copper catalysts supported on CeMn02 for CO oxidation in hydrogen rich gas streams.Iranian Journal of Chemical Engineering 12(3),3-14.
Hu,T.,Wei,Y.,Liu,S.,et al.,2007.Improvement of spark-ignition(SI)engine combustion and emission during cold-start,fueled with methanol/gasoline 1820 blends.Energy Fuels 21(1),171-178.
Huang,T.,Tsai,D., 2003.CO oxidation behavior of copper and copper oxides.Catalysis Letters 87(3-4),173—178.
Hutchings,G.J.,Mirzaei,A.A.,Joyner,R.W.,et al.,1996.Ambient temperature CO oxidation using copper manganese oxide catalysts prepared by co-precipitation:effect of ageing on catalyst performance.Catalysis Letters42(1-2),21-24.
Hutchings,G.J.,Mirzaei,A.A.,Joynerb,R.W.,et al.,1998.Effect of preparation conditions on the catalytic performance of copper manganese oxide catalysts for CO oxidation.Applied Catalysis A:General 166(1),143-152.
Iliyas,A.,2008.One-dimensional Molecular Sieves for Hydrocarbon Gold-Start Emission Control(PhD thesis).The University of New Brunswick,Frederiction.
Innovative Transport Solutions(iTrans)Pvt.Ltd.,2009.Final Report for International Council for Clean Transportation(ICCT)&the Institute for Transport and Development Policy(ITDP).TBIU,New Delhi.
International Council on Clean Transportation(ICCT),2016.India Bharat Stage VI Emission Standards.Policy Update.ICCT,New Delhi.
Iodice,P.,Senatore,A.,2012.Analysis of a Scooter Emission Behavior in Cold and Hot Conditions:Modelling and Experimental Investigations.Technical Paper 2012-01-0881.SAE,Warrendale.
Iodice,P.,Senatore,A. 2013.Road transport emission inventory in a regional area by using experimental two-wheelers emission factors.In:World Congress on Engineering,London,2013.
Iodice,P.,Senatore,A.,2015.Appraisal of pollutant emissions and air quality state in a critical Italian region:methods and results.Environmental Progress&Sustainable Energy 34(5),1497-1505.
Iodice,P.,Senatore,A.,2016.A numerical-experimental approach to assess emission performance of new generation engines during the cold transient.International Journal of Automotive and Mechanical Engineering 13(3),3599-3612.
Iodice,P.,Senatore,A.,Langella,G.,et al.,2016.Effect of ethanol—gasoline blends on CO and HC emissions in last generation SI engines within the cold-start transient:an experimental investigation.Applied Energy 179,182-190.
Ismaila,S.O.,Bolaji,B.O.,Adetunji,O.R.,et al.,2013.On vehicular emissions of petrol and diesel engines.International Journal of Engineering 1584,178-180.
Jones,C.,Cole,K.J.,Taylor,S.H.,et al.,2009.Copper manganese oxide catalysts for ambient temperature carbon monoxide oxidation:effect of calcination on activity.Molecular Catalysis A:Chemical 305(1-2),121-124.
Jones,C.,Taylor,S.H.,Burrows,A.,et al.,2008.Cobalt promoted copper manganese oxide catalysts for ambient temperature carbon monoxide oxidation.Chemical Communication 1707,1-7.
Kam,E.K.T.,Hughes,R.,1979.The effect of catalyst fouling on the performance of adiabatic packed-bed reactors-a theoretical study.Chemical Engineering Journal 18(1),93-102.
Kamrani,E.,2008.Adaptive fuzzy control for air-fuel ratio of automobile spark ignition engine.World Journal of Engineering and Technology 2(12),196-204.
Kanada,Y.,Hayashi,M.,Akaki,M.,et al.,1996.Hydrogen Added After-Burner System.Technical Paper 960346.SAE,Warrendale.
Kandylas,I.P.,Stamatelos,A.M.,1999.Engines exhaust system design based on heat transfer computation.Energy Conversion&Management 40(10),1057—1072.
Kireev,A.S.,Mukhin,V.M.,Kireev,S.G.,et al.,2009.Preparation and properties of modified hopcalite.Russian Journal of Applied Chemistry 82(1),169-171.
Kishi,N.,Hashimoto,H.,Fujimori,K.,et al.,1998.Development of the Ultra Low Heat Capacity and Highly Insulating(ULOC)Exhaust Manifold for ULEV.Technical Paper 980937.SAE,Warrendale.
Kondrat,S.A.,Davies,T.E.,Zu,Z.,et al.,2011.The effect of heat treatment on phase formation of copper manganese oxide:influence on catalytic activity for ambient temperature carbon monoxide oxidation.Journal of Catalysis 281(2),279-289.
Kramer,M.,Schmidt,T.,Stowe,K., et al.,2006.Structural and catalytic aspects of sol-gel derived copper manganese oxides as low-temperature CO oxidation catalyst.Applied Catalysis A:General 302,257-263.
Krishna,S.M.,Salam,P.A.,Tongroon,M.,et al.,2019.Performance and emission assessment of optimally blended biodieseldiesel-ethanol in diesel engine generator.Applied Thermal Engineering 155,525—533.
Lafyatis,D.S.,Ansell,G.P.,Bennett,S.C.,et al.,1998.Ambient temperature light-off for automobile emission control.Applied Catalysis B:Environmental 18(1—2),123—135.
Laing,P.,1994.Development of an Alternator-Powered Electrically-Heated Catalyst System.Technical Paper 941042.SAE,Warrendale.
Layla,A.,Azim,M.,Ali,K.A.,et al.,2008.Effects of excess cobalt oxide nanocrystallites on LaCo03 catalyst on lowering the light off temperature of CO and hydrocarbons oxidation.Iranian Journal of Chemical Engineering 27,71—77.
Lee,D.,2010.Effects of Secondary Air Injection during Cold Start of SI Engines(PhD thesis).Massachusetts Institute of Technology,Boston.
Li,H.,Andrews,G.E.,Savvidis,D.,et al.,2008.Study of thermal characteristics and emissions during cold start using an onboard measuring method for modern SI car real world urban driving.SAE International Journal of Engines 1,804—819.
Li,L.,Wang,S.,Wang,G.,et al.,2019.Effect of clamping stress on cold start performance of PEMFC.Energy Procedia 158,1744-1749.
Li,M.,Wang,D.,Shi,X.,et al.,2007.Kinetics of catalytic oxidation of CO over copper-manganese oxide catalyst.Separation and Purification Technology 57(1),147—151.
Libardi,S.H.,Skibsted,L.H.,Cardoso,D.R.,2014.Oxidation of carbon monoxide by perferrylmyoglobin.Journal of Agricultural and Food Chemistry 62(8),1950-1955.
Lisnyak,V.V.,Safonova,V.V.,Ischenko,E.V.,et al.,2012.Preparation and activity of Pt(Pd)/WP207 catalysts for H_2oxidation.Research Journal of Chemical Sciences 2(6),50-54.
Liu,X.,Wei,X.,2008.Hydrothermally Stable Ag-Zeolite Traps for Small Olefin Hydrocarbon Molecules.US Patent 20080253950.United States Patent and Trademarks Office,Washington DC.
Lopez-Perez,E.,Hermosilla,T.,Garot-Sierra,J.M.,et al.,2019.Spatial determination of traffic CO emissions within street canyons using inverse modeling.Atmospheric Pollution Research 1—8,https://doi.org/10.1016/j.apr.2019.01.019.
Lu,G.Y.,Zhang,Z.G.,2010.Close Coupled Catalyst for Purification of Exhaust Gas and the Preparation Thereof.US Patent20100048383.United States Patent and Trademark Office,Washington DC.
Ludykar,D.,Westerholm,R.,Almen,J.,1999.Cold start emissions at+22,—7 and—20℃ambient temperatures from a three-way catalyst(TWC)car:regulated and unregulated exhaust components.The Science of Total Environment 235(1—3),65-69.
Ma,T.Collings,N.,Hands,T.,1992.Exhaust Gas Ignition(EGI)—a New Concept for Rapid Light-off of Automotive Exhaust Catalyst.Technical Paper 920400.SAE,Warrendale.
Min,B.K.,Friend,C.M.,2007.Heterogeneous gold-based catalysis for green chemistry:low-temperature CO oxidation and propane oxidation.Chemical Reviews 107(6),2709-2724.
Mirzaei,A.A.,Shaterian,R.H.,Habibi,M.,et al., 2003.Characterization of copper-manganese oxide catalysts:effect of precipitate ageing upon the structure and morphology of precursors and catalysts.Applied Catalysis A:General 253(2),499-508.
Mirzaei,A.A.,Shaterian,H.R.,Joyner,R.W.,et al.,2013.Ambient temperature carbon monoxide oxidation using copper manganese oxide catalysts:effect of residual Na+acting as catalyst poison.Catalysis Communication 4,17-20.
Morgan,K.,Cole,K.J.,Goguet,A., et al.,2010.TAP studies of CO oxidation over GuMnO_x and Au/CuMnO_x catalysts.Journal of Catalysis 276,38-48.
Njagi,E.C.,Chen,C.,Genuine,H.,et al.,2010.Total oxidation of CO at ambient temperature using copper manganese oxide catalysts prepared by a redox method.Applied Catalysis B:Environmental 99(1-2),103-110.
Njagi,E.C.,Genuino,H.C.,Kingondu,C.K.,et al.,2011.Preferential oxidation of CO in H_2 rich feeds over mesoporous copper manganese oxide synthesized by a redox method.International Journal of Hydrogen Energy36(11),6768-6779.
Oser,P.,Mueller,E.,Hartel,G.,et al.,1994.Novel Emission Technologies with Emphasis on Catalyst Cold Start Improvements Status Report on VW-Pierburg Burnerl Catalyst Systems.Technical Paper 940474.SAE,Warrendale.
Paldey,S.,Gedevanishvili,S.,Zhang,W.,et al.,2005.Evaluation of a spinel based pigment systems as a CO oxidation catalyst.Applied Catalysis B:Environmental 56(3),241-250.
Patil,M.D.,Hertl,W.,Williams,J.L.,et al.,1996.In-line Hydrocarbon Adsorber System for ULEV.Technical Paper960348.SAE,Warrendale.
Patil,M.D.,Peng,Y.L.,Morse,K.E.,1998.Airless In-Line Adsorber System for Reducing Cold Start HC Emissions.Technical Paper 980419.SAE,Warrendale.
Pattrick,G.,Vander Lingen,E.,Corti,C.W.,et al.,2004.The potential for use of gold in automotive pollution control technologies:a short review.Topics in Catalysis 30(1—4),273-279.
Pillai,U.R.,Deevi,S.,2006.Room temperature oxidation of carbon monoxide over copper oxide catalyst.Applied Catalysis B:Environmental 64(1-2),146—151.
Puertolas,B.,Navlani-Garcia,M.,Lopez,J.M.,et al.,2012.Molecular simulation design of a multisite solid for the abatement of cold start emissions.Chemical Communications 48(52),6571-6573.
Pulkrabek,W.W.,2004.Engineering Fundamentals of the Internal Combustion Engine.Pearson Prentice Hall,Upper Saddle River.
Qian,K.,Qian,Z.,Hua,Q.,et al.,2013.Structure activity relationship of CuO/MnO_2 catalysts in CO oxidation.Applied Surface Science 273,357-363.
Quarles,J.,1974.Control of air pollution from new motor vehicles and new motor vehicle engines.Federal Register of United States 39(204),38250-38271.
Rajvanshi,A.K.,2002.Electric and improved cycle rickshaw as a sustainable transport system for India.Current Science 83(6),1-6.
Rani,R.,Prasad,R.,2014.Studies of carbon monoxide oxidation at ambient conditions.Recent Research in Science and Technology 6,89—92.
Raphulu,M.C.,2004.Catalytic Oxidation of Carbon Monoxide and Methane with Gold Based Catalysts(PhD thesis).University of the Witwatersrand,Johannesburg.
Roberts,A.,Brooks,R.,Shipway,P.,2014.Internal combustion engine cold-start efficiency:a review of the problem,causes and potential solutions.Energy Conversion and Management82,327-350.
Romero-Sarria,F.,Plata,J.J.,Laguna,O.H.,et al.,2014.Surface oxygen vacancies in gold based catalysts for CO oxidation.RSC Advances 4(25),13145-13152.
Roozbehani,B.,Houshmand,D.,Badakhshan,A.,2013.Thermal and catalytic degradation of polystyrene with a novel catalyst.Science International 25(4),819.
Royer,S.,Duprez,D.,2011.Catalytic oxidation of carbon monoxide over transition metal oxides.Chemcatchem 3,24-65.
Russ,S.,Thiel,M.,Lavoie,G.,1999.SI Engine Operation with Retarded Ignition:Part 2—HC Emissions and Oxidation.Technical Paper 993507.SAE,Warrendale.
Ryou,Y.S.,Lee,J.,Kim,Y.,et al.,2019.Effect of reduction treatments(H_2 vs.CO)on the NO adsorption ability and the physicochemical properties of Pd/SSZ-13 passive NOx adsorber for cold start application.Applied Catalysis A:General 569,28—34.
Santoso,H.G.,Ament,F.,2010.Cold Start Emission Strategy for Hybrid Vehicles.US 7778767.United States Patent and Trademark Office,Washington DC.
Sendilvelan,S.,Bhaskar,K.,2016.Electrically heated transition metal oxide catalyst for cold start emission reduction from gasoline engine.Indian Journal of Environmental Protection36(12),986-992.
Sendilvelan,S., Sassykova,L.,2019.Chemically heated catalytic converter design options and performance using heated metal oxides.Journal of Chemical Technology and Metallurgy 54(3),571—577.
Shi,L.,Hu,Z.,Deng,G.,et al.,2015.Carbon monoxide oxidation on copper manganese oxides prepared by selective etching with ammonia.Chinese Journal of Catalysis 36(11),1920-1927.
Shimasaki,Y.,Kato,H.,Abe,F.,et al.,1997.Development of Extruded Electrically Heated Catalyst System for ULEV Standards.Technical Paper 971031.SAE,Warrendale.
Sierra Research,Inc,2002.Review of CO Compliance Status in Selected Western Areas.SR02-09-04.Sierra Research,Inc.,Mountain View.
Sierra Research,Inc,2003.Review of Current and Future CO Emissions from On-Road Vehicles in Selected Western Areas.SR03-01-01.Sierra Research,Inc.,Mountain View.
Singh,P.,Prasad,R.,2014.Catalytic abatement of cold start vehicular CO emissions.Catalysis Industry 6(2),122-127.
Solsona,B.,Hutchings,G.J.,Garcia,T.,et al.,2004.Improvement of the catalytic performance of CuMnO_x catalysts for CO oxidation by the addition of Au.New Journal of Chemistry28,708-711.
Sothea,K.,Oanh,N.T.K.,2019.Characterization of emissions from diesel backup generators in Cambodia.Atmospheric Pollution Research 10,345—354.
Summers,J.,Skowron,J.,Miller,M.,1993.Use of Light-off Catalysts to Meet the California LEV/ULEV Standards.Technical Paper 930386.SAE,Warrendale.
Sun,J.,Sivashankar,N.,1998.Issues in cold start emission control for automotive IC engines.In:The American Control Conference,Philadelphia,1998.
Takei,Y.,Hirohiko,H.,Okada,M.,et al.,1993.Effect of Gasoline Components on Exhaust Hydrocarbon Components.Technical Paper 932670.SAE,Warrendale.
Tanaka,Y.,Utaka,T.,Kikuchi,R.,et al.,2003.Water gas shift reaction for the reformed fuels over Cu/MnO catalysts prepared via spinel-type oxide.Journal of Catalysis 215(2),271-278.
Tang,Z.R.,Kondrat,S.A.,Dickinson,C.,et al.,2011.Synthesis of high surface area CuMn_2O_4 by supercritical anti-solvent precipitation for the oxidation of CO at ambient temperature.Catalysis Science&Technology 1(5),740—746.
Taylor,S.H.,Hutchings,G.J.,Mirzaei,A.A.,1999.Copper zinc oxide catalysts for ambient temperature carbon monoxide oxidation.Chemical Communications 15,1373—1374.
Tingvall,B.,Pettersson,E.,2009.Demonstration of Multi Gas Exhaust Measurements during Cold Start Conditions.Lulea University of Technology,Lulea.
Ueno,M.,Akazaki,S.,Yasui,Y.,et al.,2000.A Quick Warm-Up System during Engine Start-Up Period Using Adaptive Control of Intake Air and Ignition Timing.Technical Paper000551.SAE,Warrendale.
Vasic,A.M.,Weilenmann,M., 2006.Comparison of real-world emissions from two wheelers and passenger cars.Environmental Science&Technology 40(1),149-154.
Veprek,S.,Cocke,D.L.,Kehl,S.,et al., 1986.Mechanism of the deactivation of hopcalite catalysts studied by XPS,ES and other techniques.Journal of Catalysis 100(1),250—263.
Wang,W.,Lahti,J.L.,Gillanders,C.A.,et al.,2009.Method for Onboard Diagnosis of Cold Start Emissions Reduction Control Strategy.US 7630826.United States Patent and Trademark Office,Washington DC.
Weilenmann,M.,Soltic,P.,Saxer,C.,et al.,2005.Regulated and nonregulated diesel and gasoline cold-start emissions at different temperatures.Atmospheric Environment 39(13),2433-2441.
Williams,J.L.,Patil,M.D.,Hertl,W.,1996.By-pass Hydrocarbon Adsorber System for ULEV.Technical Paper 960343.SAE,Warrendale.
Yusuf,A.A.,Inambao,F.L.,2019.Effect of cold start emissions from gasoline-fueled engines of light-duty vehicles at low and high ambient temperatures:recent trends.Case Studies in Thermal Engineering 14,100417.
Zaki,M.I.,Hasan,M.A.,Pasupulety,L.,2009.Influence of CuOx additives on CO oxidation activity and related surface and bulk behaviors of Mn_2O_3,Cr_2O_3 and W03 catalysts.Applied Catalysis A:General 198,247—259.
Zhao,F.,Gong,M.,Zhang,G.,et al.,2015.Effect of the loading content of GuO on the activity and structure of CuO/Ce-Mn-O catalysts for CO oxidation.Journal of Rare Earths 33(6),604-610.
Zhou,L.,Hua,J.,Wei,H.,et al.,2019.An experimental investigation on low load combustion stability and coldfiring capacity of a gasoline compression ignition engine.Engineering 5(3),558-567.
Zhou,Y.,Wang,Z.,Liu,C.,2014.Perspective on CO oxidation over Pd-based catalysts.Catalysis Science and Technology 1,69—81.
Zhu,M.,Xie,X.,Wu,K.,et al.,2019.Experimental investigation of the effect of membrane water content on PEM fuel cell cold start.Energy Procedia 158,1724—1729.