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NTIS 바로가기청정기술 = Clean technology, v.21 no.3, 2015년, pp.200 - 206
변창기 (충남대학교 에너지과학기술대학원) , 임효빈 (충남대학교 에너지과학기술대학원) , 박지혜 (충남대학교 에너지과학기술대학원) , 백정훈 (충남대학교 에너지과학기술대학원) , 정정민 (충남대학교 에너지과학기술대학원) , 윤왕래 (한국에너지기술연구원) , 이광복 (충남대학교 화학공학교육학과)
In order to investigate the effect of cerium oxide addition, Cu-ZnO-CeO2 catalysts were prepared using co-precipitation method for water gas shift (WGS) reaction. A series of Cu-ZnO-CeO2 catalyst with fixed Cu Content (50 wt%, calculated as CuO) and a given ceria content (e.g., 0, 5, 10, 20, 30, 40 ...
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Mikkelsen, M., Jorgensen, M., and Krebs, F. C., "The Teraton Challenge. A Review of Fixation and Transformation of Carbon Dioxide," Energy Environ. Sci., 3, 43-81 (2010).
Wu, H., Parola, V. L., Pantaleo, G., Puleo, F., Venezia, A. M., and Liotta, L. F., “Ni-Based Catalysts for Low Temperature Methane Steam Reforming: Recent Results on Ni-Au and Comparison with Other Bi-Metallic Systems,” Catal., 3, 563-583 (2013).
Agrell, J., Birgersson, H., Boutonnet, M., Melian-cabrera, I., Navarro, R. M., and Fierro, J. L. G., “Production of Hydrogen from Methanol over CuZnO Catalysts Promoted by ZrO 2 and Al 2 O 3 ,” J. Catal., 219, 389-403 (2003).
Trimm, D. L., “Minimisation of Carbon Monoxide in a Hydrogen Stream for Fuel Cell Application,” Appl. Catal. A: General, 296, 1-11 (2005).
Gokhale, A. A., Dumesic, J. A., and Mavrikakis, M., “On the Mechanism of Low-temperature Water Gas Shift Reaction on Copper,” J. American Chem. Soc., 130, 1402-1414 (2008).
Mendes, D., Mendes, A., Madeira, L. M., Sousa, J. M., and Basile, A., “The Water Gas Shift Reaction: From Conventional Catalytic Systems to Pd-based Membrane Reactors -A Review,” Asia-Pacific J. Chem. Eng., 5, 111-137 (2010).
Qi, F., Weber, A., and Flytzani-Stephanopoulos, M., “Nano-structured Au-CeO 2 Catalysts for Low-temperature Water-gas Shift,” Catal. Lett., 77, 87-95 (2001).
Bunluesin, T., Gorte, R. J., and Graham, G. W., “Studies of the Water-gas-shift Reaction on Ceria-supported Pt, Pd, and Rh: Implications for Oxygen-storage Properties,” Appl. Catal. B: Environ., 15, 107-114 (1998).
Odabaşı, Ç., Günay, M. E., and Yıldırım, R., “Knowledge Extraction for Water Gas Shift Reaction over Noble Metal Catalysts from Publications in the Literature between 2002 and 2012,” Int. J. Hydro. Energy, 39(11), 5733-5746 (2014).
Jeong, D. W., Jang, W. J., Shim, J. O., Han, W. B., and Roh, H. S., “Low-temperature Water-gas Shift Reaction over Supported Cu Catalysts,” Renewable Energy, 65, 102-107 (2014).
Rhodes, C., Hutchings, G. J., and Ward, A. M., “Water-gas Shift Reaction: Finding the Mechanistic Boundary,” Catal. Today, 23, 43-58 (1995).
Shishido, T., Yamamoto, M., Atake, I., Li, D., Tian, Y., Morioka, H., Honda, M., Sano, T., and Takehira, K., “Cu/Zn-based Catalysts Improved by Adding Magnesium for Water-gas Shift Reaction,” J. Molecular Catal. A: Chem., 253, 270-278 (2006).
Figueiredo, R. T., Santos, M. S., Andrade, H. M. C., and Fierro, J. L. G., “Effect of Alkali Cations on the CuZnOAl 2 O 3 Low Temperature Water Gas-shift Catalyst,” Catal. Today, 172, 166-170 (2011).
Saito, M., Tomoda, K., Takahara, I., Murata, K., and Inaba, M. “Effects of Pretreatments of Cu/ZnO-based Catalysts on their Activities for the Water-gas Shift Reaction,” Catal. Lett., 89, 11-13 (2003).
Ginés, M. J. L., Amadeo, N., Laborde, M., and Apesteguia, C. R., “Activity and Structure-sensitivity of the Water Gas Shift Reaction over CuZnAl Mixed Oxide Catalysts,” Appl. Catal. A: General, 131, 283-296 (1995).
Wang, X., Gorte, R. J., and Wagner, J. P., “Deactivation Mechanisms for Pd/ceria during the Water-gas-shift Reaction,” J. Catal., 212, 225-230 (2002).
Twigg, M, V., and Spencer, M. S., “Deactivation of Supported copper Metal Catalysts for Hydrogenation Reactions,” Appl. Catal. A: General, 212, 161-174 (2001).
Kumar, P., and Idem. R., “A Comparative Study of Copperpromoted Water Gas Shift (WGS) Catalysts,” Energy & fuels, 21, 522-529 (2007).
Fernández-Garcıa, M., Rebollo, E. G., Ruiz, A. G., Conesa, J. C., and Soria, J., “Influence of Ceria on the Dispersion and Reduction/Oxidation Behaviour of Alumina-supported Copper Catalysts,” J. Catal., 172, 146-159 (1997).
Huber, F., Meland, H., Ronning, M., Venvik, H., and Holmen, A., “Comparison of Cu-Ce-Zr and Cu-Zn-Al Mixed Oxide Catalysts for Water-gas Shift,” Topics in Catal., 45, 101-104 (2007).
Li, L., Zhan, Y., Zheng, Q., Zheng, Y., Chen, C., She, Y., Lin, X., and Wei, K., “Water-gas Shift Reaction over CuO/CeO 2 Catalysts: Effect of the Thermal Stability and Oxygen Vacancies of CeO 2 Supports Previously Prepared by Different Methods,” Catal. Lett., 130, 532-540 (2009).
Jacobs, G., Crawford, A., Williams, L., Patterson, P. M., and Davis, B. H., “Low Temperature Water Gas Shift: Comparison of Thoria and Ceria Catalysts,” Appl. Catal. A: General, 267, 27-33 (2004).
Djinović, P., Jurka, B., and Pintar, A., “Calcination Temperature and CuO Loading Dependence on CuO-CeO 2 Catalyst Activity for Water Gas Shift Reaction,” Appl. Catal. A: General, 347, 23-33 (2008).
Pradhan, S., Reddy, A. S., Devi, R. N., and Chilukuri, S., “Copper-based Catalysts for Water Gas Shift Reaction: Influence of Support on their Catalytic Activity,” Catal. Today, 141, 72-76 (2009).
Li, Y., Qi, F., and Flytzani-Stephanopoulos. M., “Low-temperature Water Gas Shift Reaction over Cu-and Ni-loaded Cerium Oxide Catalysts,” Appl. Catal. B: Environ., 27, 179-191 (2000).
Liu, W., and Flytzani-stephanopoulos, M., “Total Oxidation of Carbon Monoxide and Methane over Transition Metal Fluorite Oxide Composite Catalysts I. Catalyst Composition and Activity,” J. Catal., 153, 304-316 (1995).
Liu, W., and Flytzani-stephanopoulos, M., “Total Oxidation of Carbon-Monoxide and Methane over Transition Metal Fluorite Oxide Composite Catalysts II. Catalyst Characterization and Reaction-Kinetics,” J. Catal., 153, 317-332 (1995).
Jeong, D. W., Na, H. S., Shim, J. O., Jang, W. J., Roh, H. S., Jung, U. H., and Yoon, W. L., “Hydrogen Production from Low Temperature WGS Reaction on co-precipitated Cu-CeO 2 Catalysts: An Optimization of Cu Loading,” Int. J. Hydro. Energy, 39, 9135-9142 (2014).
Rønning, M., Huber, F., Meland, H., Venvik, H., Chen, D., and Holmen, A., “Relating Catalyst Structure and Composition to the Water-gas Shift Activity of Cu-Zn-based Mixed-oxide Catalysts,” Catal. Today, 100, 249-254 (2005).
Reitz, T. L., Lee, P. L., Czaplewski, K. F., Lang, J. C., Popp, K. E., and Kung, H. H., “Time-Resolved XANES Investigation of CuO/ZnO in the Oxidative Methanol Reforming Reaction,” Fournal of Catal., 199, 193-201 (2001).
Shan, W., Feng, Z., Li, Z., Zhang, J., Shen, W., and Li, C., “Oxidative Steam Reforming of Methanol on Ce0.9Cu0.1OY Catalysts Prepared by Deposition-precipitation, Coprecipitation, and Complexation-combustion Methods,” J. Catal., 228, 206-217 (2004).
Patel, S. and Pant, K. K., “Selective Production of Hydrogen Via Oxidative Steam Reforming of Methanol Using Cu-Zn-Ce-Al Oxide Catalysts,” Chem. Eng. Sci., 62, 5436-5443 (2007).
Agrell, J., Birgersson, H., Boutonnet, M., Melian-Cabrera, I., Navarro, R. M., and Fierro, J. L. G., “Production of Hydrogen from Methanol over Cu/ZnO Catalysts Prometed by ZrO 2 and Al 2 O 3 ,” J. Catal., 219, 389-403 (2003).
Zhang, D., Yin, H., Zhang, R., Xue, J., and Jiang, T., “Gas Phase Hydrogenation of Maleic Anhydride to γ-Butyrolactone by Cu-Zn-Ce Catalyst in the Presence of n-Butanol,” Catal. Lett., 122, 176-182 (2008).
Avgouropoulos, G., and Ioannides, T., “Selective CO Oxidation over CuO-CeO 2 Catalysts Prepared via the Urea-nitrate Combustion Method,” Appl. Catal. A: General, 244, 155-167 (2003).
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