Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi

DOĞU, Timur

Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi

Yürütücü

Timur DOĞU (Orta Doğu Teknik Üniversitesi, Ankara, Türkiye)

1 1

Proje Grubu: MAG Sayfa Sayısı: 87 Proje No: 111M338 Proje Bitiş Tarihi: 01.10.2013 Metin Dili: Türkçe İndeks Tarihi: 29-07-2022

Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi

Öz:

Anahtar Kelime:

Erişim Türü: Erişime Açık

Athawale A.A., Bapat M.S., Desai P.A., “Hydroxide directed routes to synthesize nanosized cubic ceria (CeO2)”, Journal of Alloys and Compounds, 484 (2009) 211-217.
Barelli, L., Bidini G., Gallorini F., Servili S. Hydrogen production through sorption-enhanced steam methane reforming and membrane theology. Energy 33 (2008) 554-570.
Barras B.S., Melo D.M.A., Libs S., Kiennemann A., “CO2 reforming of methane over La2NiO4/α-Al 2O3 prepared by microwave assisted self-combustion method”, Applied Catalysis A:General, 378 (2010) 69-75.
Baysar, A., Kuester, L., ‘Mikrodalgalarla ısıtılan akışkan yataklı reaktörlerde saf silisyum üretimi’, 1. Ulusal Kimya Müh. Kongre Kitabı, (1994) 528-537.
Cerovic L., Lair V., Lupan O., Cassir M., Ringuede A., “Electrochemical synthesis and characterization of nanorods, nanocolumnar ceria-based thin films on different glass substrates”, Chemical Physics Letters, 494 (2010) 237-242.
Chandradass J., Nam B., Kim K.H., “Fine tuning of gadolinium doped ceria electrolyte nanoparticles via reverse microemulsion process”, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 348 (2009) 130-136.
Chen SQ, Liu Y. “LaFe yNi1-yO3 supported nickel catalysts used for steam reforming of ethanol”, Int. J. Hydrogen Energy 2009; 34:4735-46.
Chen ZX, Elnashaie SSEH. Economics of the clean fuel hydrogen in a novel autothermal reforming process. Ind. Eng. Chem. Res. 2005; 44:4834-40.
Ciambelli P., Palma V., Ruggiero A., “Low temperature catalytic steam reforming of ethanol. 1. The effect of the support on the activity and stability of Pt catalysts”, Applied Catalysis B: Environmental, 96 (2010) 18-27.
Ciambelli P., Palma V., Ruggiero A., “Low temperature catalytic steam reforming of ethanol. 2.Preliminary kinetic investigation of Pt/CeO2 catalysts”, Applied Catalysis B: Environmental, 96 (2010) 190-197.
Coleman LJI, Epling W, Hudgins RR, Croiset E. Ni/Mg-Al mixed oxide catalyst for the steam reforming of ethanol. Applied Catalysis:A General 2009; 363:52-63.
Dai Q, Wang X, Chen G, Zheng Y, Lu G. Direct synthesis of Cerium(III) Incorporated SBA-15 Mesoporous Molecular Sieves by Two-step Synthesis Method. Microporous Mesoporous Mater.2007; 100:268.
Deluga GA, Salge JR, Schmidt LD, Verykios XE. Renewable hydrogen from ethanol by autothermal reforming. Science 2004; 303(5660):993-7.
Djinović P., Osojnik Črnivec I.G., Erjavec B., Pintar A., “Effect of synthesis parameters on morphology and activity of bimetallic catalysts in CO2–CH4 reforming”, Chemical Engineering Journal, 207-208 (2012), 299-307
Dogu T, Varisli D. Alcohols as alternatives to petroleum for environmentally clean fuels and petrochemicals. Turk. J. Chem. 2007; 31:551-67.
Fidalgo B., Dominguez A., Pis J.J., Menendez J.A., “Microwave-assisted dry reforming of methane”, International Journal of Hydrogen Energy, 33 (2008) 4337-4344.
Frusteri F., Freni S., Chiodo V., Donato S., Bonura G., Cavallaro S., “Steam and auto-thermal reforming of bio-ethanol over MgO and CeO2 Ni supported catalysts”, International Journal of Hydrogen Energy, 31 (2006) 2193-2199.
Garcia, E.Y., Laborde, M.A., ‘Hydrogen production by the steam reforming of ethanol: Thermodynamic analysis’, Int. J. Hydrogen Energy 16 (1991) 307-312.
Gu F., Wang Z., Han D., Shi C., Guo G., “Reverse micelles directed synthesis of mesoporous ceria nanostructures”, Materials Science and Engineering B, 139 (2007) 62-68.
Gucbilmez Y, Dogu T, Balci S. Vanadium incorporated high surface area MCM-41catalysts. Catal. Today 2004;100:473-77.
Gucbilmez Y, Dogu T, Balci S.Ethylene and acetaldehyde production by selective oxidation of ethanolusing mesoporous V-MCM-41 catalysts. Ind. Eng. Chem. Res. 2006;45: 3496-3542.
Haryanto A., Fernando S., Murali N., Adhikari S. Current status of hydrogen production techniques by steam reforming of ethanol. Energy & Fuels 19 (2005) 2098-2106.
Hu J., Li Y., Zhou X., Cai M., “Preparation and characterization of ceria nanoparticles using crystalline hydrate cerium propionate as precursor”, Materials Letters 61 (2007) 4989-4992.
Huber GW, Shabaker JW, Dumesic JA. Raney “Ni-Sn catalyst for H2 production from biomass-derived hydrocarbons”, Science, 300 (2003) 2075.
Hwang C.-C., Huang T.-H., Tsai J.- S., Lin C.-S., Peng C.-H., “Combustion synthesis of nanocrystalline ceria (CeO2) powders by a dry route”, Materials Science and Engineering B, 132 (2006) 229-238.
Ionnides, T., ‘Thermodynamic analysis of ethanol processors for fuel cell applications’, Journal of Power Sources, 92 (2001) 17-25.
Iwasaki, Y., Suzuki, Y., Kitajima T., Sakurai M., Kameyama H. Non-equilibrium hydrogen 9 production from eethanol using CO2 absorption ceramic and precious metal catalysts. J. Chem. Eng. Jpn. 40 (2007) 178-185.
Kresge CT, Leonowicz ME, Roth WJ, Vartuli JC, Beck JS. A new family of mesoporous molecular sieves prepared with liquid crystal templates. Nature 1992;359:710.
Li J., Hao Y., Li H., Xia M., Sun X., Wang L., “Direct synthesis of CeO2/SiO2 mesostructured composite materials via sol-gel process”, Microporous and Mesoporous Materials, 120 (2009) 421-425.
Lima S.M., Silva A.M., Costa L.O.O., Graham U.M., Jacobs G., Davis B.H., Mattos L.V., Noronha F.B., “Study of catalyst deactivation and reaction mechanism of steam reforming, partial oxidation, and oxidative steam reforming of ethanol over Co/CeO2 catalyst”, Journal of Catalysis, 268 (2009) 268-281.
Liotta L.F., Carlo G. D., Puelo F., Pantaleo G., Deganello G., “Mesoporous SBA-15 silica modified with cerium oxide: Effect of ceria loading on support modification”, 10th International Symposium “Scientific Bases for the Preparation of Heterogeneous Catalysts” manuscrips, 2010.
Luo L., Wang J., Zhao X., “Template synthesis and characterization of mesoporous CeO2 and Ru-loaded mesoporous CeO2”, Indian Journal of Chemistry, 48(A) (2009) 327-332.
Lysikov A.I., Trukhan S.N., Okunev A.G. Sorption enhanced hydrocarbons reforming for fuel cell powered generators. Int. J. Hydrogen Energy 33 (2008) 3061-3066.
Mastalir A., Frank B., Szizybalski A., Soerijanto H., Deshpande A., Niederberger M., Schomäcker R., Schlögl R., Ressler T., “Steam reforming of methanol over Cu/ZrO2/CeO2 catalysts: a kinetic study”, J. Catal. 230, (2005) 464-475
Morris S.M., Fulvio P.F., Jeroniec M. Ordered mesoporous alumina-supported metal oxides. JACS 130 (2008) 15210-14216.
Nalbant A, Dogu T, Balci S, Ni and Cu incorporated mesoporous catalytic materials. J. Nanoscience Nanotechnol. 2005; 8:549-56.
Ni M., Leung DYC, Leung MKH. A review on reforming bio-ethanol for hydrogen production. Int. J. Hydrogen Energy 2007; 32:3238-47.
Ozdogan E, Dogu T, Dogu G. Ni-MCM-41 type mesoporous catalysts synthesized by one-pot hydrothermal procedure for steam reforming of ethanol. Int. J. Chem. Reactor Eng. 2007; 5:A111.
Profwti LPR, Dias JAC, Assaf JM, Assaf EM. “Hydrogen production by steam reforming of ethanol over Ni-based catalysts promoted with noble metals” J. Power Sources 2009; 190:525-33.
Profeti LPR, Ticianelli EA, Assaf EA. Production of hydrogen via steam reforming of biofuels on Ni/CeO2 -Al2O3 catalysts promoted by noble metals” Int. J. Hydrogen Energy 2009; 34:5049-60.
Puertolas B., Solsona B., Agouram S., Murillo R., Mastral A.M., Aranda A., Taylor S.H., Garcia T., “The catalytic performance of mesoporous cerium oxides prepared through a nanocasting route for the total oxidation of naphthalene”, Applied Catalysis B: Environmental, 93 (2010) 395-405.
Rao G.R., Mishra B.G., “Structural, redox and catalytic chemistry of ceria based materials”, Bulletin of the Catalysis Society of India, 2 (2003) 122-134.
Rass-Hansen J, Johansson R, Moller M, Christensen CH. Steam reforming of technical bioethanol for hydrogen production. Int. J. Hydrogen Energy 2008; 33:4547-54.
Schrope M. Which way to energy utopia? Nature 2001; 414:682-4.
Sener C, Dogu T, Dogu G. Effects of synthesis conditions on the structure of Pd incorporated MCM-41 type mesoporous nanocomposite catalytic materials with high Pd/Si ratios. Microporous Mesoporous Mater. 2006; 94:89-98.
Sener C, Dogu T, Dogu G. Direct hydrothermal synthesis of palladium incorporated silicate structured mesoporous catalysts. Turk. J. Chem. 2007; 31:473.
Shen, W., Komatsubara, K., Hagiyama, T., Yoshida, A., Naito, S., ‘Steam reforming of methane over ordered mesoporous Ni-Mg-Al oxides’, Chem. Commun., (2009) 6490-6492.
Silva A.M., Souza K.R., Jacobs G., Graham U.M., Davis B.H., Lisiane V.M., Noronha F.B., “Steam and CO2 reforming of ethanol over Rh/CeO 2 catalyst”, Applied Catalysis B: Environmental, 102 (2011) 94-109.
Song H., Mirkelamoglu B., Ozkan U.S., “Effect of cobalt precursor on the performance of ceria-supported cobalt catalysts for ethanol steam reforming”, Applied Catalysis A: General, 382 (2010) 58-64.
Song H., Ozkan U.S., “Ethanol steam reforming over Co-based catalysts: Role of oxygen mobility”, Journal of Catalysis, 261 (2009) 66-74.
Song H, Tan B, Ozkan US. Novel synthesis techniques for preparation of Co/CeO2 as ethanol steam reforming catalysts. Catal. Lett. 2009; 132:422-29.
Strauss, C.R., Trainor, R.W., ‘Invited rewiev developments in microwave-assisted organic chemistry’, Aust. J. Chem., 48 (1995) 1665-1692.
Sun J., Wang Y., Li J., Xiao G., Zhang L., Li H., Cheng Y., Sun C., Cheng Z., Dong Z., Chen L., H2 production from stable ethanol steam reforming over catalyst of NiO based on flowerlike CeO2 microspheres”, International Journal of Hydrogen Energy, 35 (2010) 3087-3091.
Suslu OS, Becerik I. On-board fuel processing for a fuel cell-heat engine hybrid system. Energy & Fuels 2009; 23:1858-73.
Terribile D., Trovarelli A., Llorca J., Leitenburg C., Dolcetti G., “The synthesis and characterization of mesoporous high-surface area ceria prepared using a hybrid organic/inorganic route”, Journal of Catalysis, 178 (1998) 299-308.
Vasudeva, K., Mitra, N., Umasankar, P., Dhingra, S.C., ‘Steam reforming of ethanol for hydrogen production: Thermodynamic analysis’, Int. J. Hydrogen Energy, 21 (1996) 13-18.
Vizcaino AJ, Carrero A, Calles JA. “Ethanol steam reforming on Mg and Ca modified Cu-Ni/SBA-15 catalysts” Catal. Today 2009; 146: 63-70.
Wang T., Sun D.C., “Preparation and characterization of nanometer-scale powders ceria by electrochemical deposition method”, Materials Research Bulletin, 43 (2008) 1754-1760.
Wang X., Wang N., Wang L. Hydrogen production by sorption enhanced steam reforming of propane. Int. J. Hydrogen Energy (2010) 1-7.
Wang Y.N.,, Rodriguez A.E. Hydrogen production from methane reforming coupled with in situ CO2 capture: Conceptual parametric study. Fual 84 (2005) 1778-1784.
Ye JL, Wang YQ, Liu Y, Wang H. “Stem reforming of ethanol over Ni/CexTi1-xO2” catalysts. Int. J. Hydrogen Energy 2008; 33:6602-11.
Yi K.B., Harrison D.P. Low pressure sorption enhanced hydrogen production. Ind. Eng. Chem. Res. 44 (2005) 1665-1669.
Ying F., Wang S., Au C.-T., Lai S.-Y., “Highly active and stable mesoporous Au/CeO2 catalysts prepared from MCM-48 hard-template”, Microporous and Mesoporous Materials, (2011), in press.
Yuan Q., Yin A.X., Luo C., Sun L.D., Zhang Y.W., Duan W.T., Liu H.C., Yan C.H. Facile synthesis for ordered mesoporous aluminas with high thermal stability. JACS 130 (2008) 3465-3472.
Zawadzki M., “Preparation and characterization of ceria nanoparticles by microwave-assisted solvothermal process”, Journal of Alloys and Compounds 454 (2008) 347-351.

APA	DOĞU T (2013). Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. , 1 - 87.
Chicago	DOĞU Timur Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. (2013): 1 - 87.
MLA	DOĞU Timur Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. , 2013, ss.1 - 87.
AMA	DOĞU T Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. . 2013; 1 - 87.
Vancouver	DOĞU T Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. . 2013; 1 - 87.
IEEE	DOĞU T "Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi." , ss.1 - 87, 2013.
ISNAD	DOĞU, Timur. "Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi". (2013), 1-87.

APA	DOĞU T (2013). Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. , 1 - 87.
Chicago	DOĞU Timur Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. (2013): 1 - 87.
MLA	DOĞU Timur Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. , 2013, ss.1 - 87.
AMA	DOĞU T Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. . 2013; 1 - 87.
Vancouver	DOĞU T Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi. . 2013; 1 - 87.
IEEE	DOĞU T "Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi." , ss.1 - 87, 2013.
ISNAD	DOĞU, Timur. "Etanol reformlama ile yüksek hidrojen verimi için adsorpsiyon - reaksiyon kombinasyonu v uygun mezogözenekli katalizörlerin geliştirilmesi". (2013), 1-87.