Energy Science and Technology

Abstract: Microwave catalytic technology is a promising technology for flue gas treatment. Cu/zeolite was used as catalyst for microwave catalytic desulfurization and denitrification and for microwave catalytic reduction of SO₂ and NOx with ammonium bicarbonate (NH₄HCO₃) as a reducing agent. Microwave catalytic desulfurization and denitrification efficiency achieved 76.1 and 81.8% separately. The reaction efficiency of microwave catalytic reduction of SO₂ and NO_x could be up to 99.8 and 92.8% respectively. The physico-chemical properties of Cu/zeolite catalysts were characterized by X-ray diffraction analysis (XRD), Brunauer-Emmett-Teller measurements (BET), X-ray photoelectron spectrum analysis (XPS), scanning electron microscopy (SEM).The XPS results indicate that sulfide (SO4^2-), element sulfur (S⁰) and NH₄⁺ species exist on the catalyst surface after the reaction. Microwave catalytic SO₂ and NO_x removal follows Langmuir — Hinshelwood(L-H) kinetics.
Key words: Simultaneous desulfurization & denitrification; Microwave catalytic technology; Cu/zeolite; Characterization

Simultaneous desulfurization & denitrification; Microwave catalytic technology; Cu/zeolite; Characterization

X. L. Zhang, David, O. H., Colleen, L. D., & Michael, P. M. (2001). Microwave assisted catalytic reduction of sulfur dioxide with methane over MoS₂ catalysts. Applied Catalysis B: Environmental, 33(2), 137-148.

Carja, G., Kameshima, Y., Okada, K., & Madhusoodana, C. D. (2007). Mn–Ce/ZSM5 as a new superior catalyst for NO reduction with NH₃. Applied Catalysis B: Environmental, 73(1-2), 60-64.

C. H. Wang, S. S. Lin, P. C. Sung, & H. S. Weng (2003). Catalytic reduction of SO₂ over supported transition-metal oxidecatalysts with C₂H₄ as a reducing agent. Applied Catalysis B: Environmental, 40(4), 331-345.

Wallin, M., Karlsson, C. J., Skoglundh, M., & Anders, P. (2008). Selective catalytic reduction of NO_x with NH₃ over zeolite H–ZSM-5: influence of transient ammonia supply. Journal of Catalysis, 218(2), 354-364.

Escribano, A. S., Alvarez, C. M., Ramos, I. R., Ruiz, A. G., & Fierro, J. L. G. (1993). Decomposition of NO on Cu-loaded zeolites. Catalysis Today, 17(1-2),167-174.

Krishna, K., & Makkee, M. (2005). Coke formation over zeolites and C_eO₂- zeolites and its influence on selective catalytic reduction of NO_x. Applied Catalysis B: Environmental, 62(1-2), 35-44.

Simona, B., Antonella, G., Marta, L., Vittorio, R. (2005). C_uO based catalysts on modified acidic silica supports tested in the de-NO_x reduction. Ultrasonics Sonochemistry, 12(4), 307-312.

Vicente, S.E., Montanari, T., Busca, G. (2005). Low temperature selective catalytic reduction of NO_x by ammonia over H-ZSM-5: an IR study. Applied Catalysis B: Environmental, 58(1-2), 19-23.

G. Y. Xie, Z. Y. Liu, Z. P. Zhu, Q. Y. Liu, J. Ge, & Z. G. Huang (2004). Simultaneous removal of SO₂ and NOx from flue gas using a C_uO/Al₂O₃ catalyst sorbent II: Promotion of SCR activity by SO₂ at high temperatures. Journal of Catalysis, 224(1), 36-41.

Y. X. Guo, Z. Y. Liu, Y. M. Li, & Q. Y. Liu (2007). NH3 regeneration of SO₂-captured V2O5/AC catalyst-sorbent for simultaneous SO₂ and NO removal. Journal of Fuel Chemistry Technology, 35(2), 344-348.

Q .,Yu, H. M., Yang, K. S., Zeng, Z. W., Zhang, & G., Yu (2007). Simultaneous removal of NO and SO₂ from dry gas stream using non-thermal plasma. Journal of Environmental Science, 19(11), 1393-1397.

Ighigeanu, D, Martin, D., Zissulescu, E., Macarie, R., Oproiu, C., Cirstea. E., Iovu, H., Calinescu, I., Iacob, N. (2005). SO₂ and NO_x removal by electron beam and electrical discharge induced non-thermal plasmas. Vacuum, 77(4), 493-500.

Mok, Y. S., Lee, H. W., & Hyun, Y. J. (2001). Flue gas treatment using pulsed corona discharge generated by magnetic pulse compression modulator. Journal of Electrostatics, 53(3),195–208.

Kim, H., Han, J., Kawaguchi, I., & Minami, W. (2007). Simultaneous Removal of NO_x and SO₂ by a Nonthermal Plasma Hybrid Reactor. Energy &Fuels, 21(1), 141-144.

Y. C. Chang, & S. K. Dong (2001). Microwave induced reactions of sulfur dioxide and nitrogen oxides in char and anthracite bed. Carbon, 39(8),1159–1166.

DX Zhang, AM Yu, & Jin QH(1997). Studies on microwave-carbon reduction method for the treatment of nitric oxide. Chemistry Journal of Chinese University, 18(2), 1271-1274.

Marilena, T. R., Diana, I. M., & Ioan, C. (2003). Emission control of SO₂ and NO_x by irradiation methods. Journal of Hazardous Materials, 97(1), 145-158.

Ibe, M., Gomez, S., Malinger, K. A., Fanson, P., & Suib, S. L. (2007). Microwave-assisted desulfurization of NOx storage-reduction catalyst. Applied Catalysis B: Environmental, 69(3-4),235-239.

Kim, S. B., & Hong, S. C.(2002). Kinetic study for photocatalytic degradation of volatile organic compounds in air using thin film TiO₂ photocatalyst. Applied Catalysis B: Environmental, 35(4), 305-315.