Revista Valore

A oxidação catalítica seletiva de acetonitrila (OCS-ACN) tem se destacado como uma alternativa energeticamente mais eficiente que a combustão tradicional para tratamento desse poluente. Nesse trabalho foi estudada a oxidação da acetonitrila utilizando Cu-ZSM-5, Fe-ZSM-5 e Co-ZSM-5 como catalisadores. Esses catalisadores foram preparados por trocas iônicas e caracterizados por Difratometria de Raios X (DRX) e Redução com Hidrogênio a Temperatura Programada (TPR-H₂). Os resultados de DRX evidenciaram a presença de óxidos nos catalisadores (Cu e Fe)-ZSM-5. Os catalisadores (Cu e Fe)-ZSM-5 foram reduzidos em mais de uma etapa, enquanto a ausência de picos de redução em Co-ZSM-5 indica que o cobalto está predominantemente em posição de intercâmbio. Na OCS-ACN foi observada a seguinte ordem de atividade Cu-ZSM-5> Fe-ZSM-5> Co-ZSM-5. Cu-ZSM-5 foi o catalisador mais ativo e altamente seletivo a N₂ entre 350-500 ºC. As nanopartículas de CuO sobre a zeólita ZSM-5 desempenham um papel fundamental na atividade e seletividade desse catalisador.

AMAKI, E., & SAHRAEI, R. Preparation, characterization and optical properties of nanostructured undoped and Cu doped ZnO thin films. Bulgarian Chemical Communications, v. 48, p. 131-137, 2016.ARMSTRONG et al., 2018.

AZIZ, A., SAJJAD, M., KIM, M., & KIM, K. S. An efficient Co-ZSM-5 catalyst for the abatement of volatile organics in air: effect of the synthesis protocol. International journal of environmental science and technology, v. 15, n. 4, p. 707-718, 2018.

BRACHT, F. Acetonitrila (CAS No. 75-05-8). Revista Virtual de Química, v. 3, n. 1, p. 51-52, 2011.

CHEN, M., WANG, Y., LIANG, T., & YANG, Z. (2018, February). Hydrogen production by steam reforming of bio-oil aqueous fraction over Co-Fe/ZSM-5. In IOP Conference Series: Earth and Environmental Science. IOP Publishing, v 113, n. 1, p. 012081, 2018.

FENG, B., WANG, Z., SUN, Y., ZHANG, C., TANG, S., LI, X., & HUANG, X. Size controlled ZSM-5 on the structure and performance of Fe catalyst in the selective catalytic reduction of NOx with NH3. Catalysis Communications, v. 80, p. 20-23, 2016.

JIANG, L., SUI, Y., QI, J., CHANG, Y., HE, Y., MENG, Q., WEI F., SUN Z., & JIN, Y. Structure Dependence of Fe‐Co Hydroxides on Fe/Co Ratio and Their Application for Supercapacitors. Particle & Particle Systems Characterization, v. 34, n. 2, p. 1600239, 2017.

KAMAL, M. S., RAZZAK, S. A., & HOSSAIN, M. M. Catalytic oxidation of volatile organic compounds (VOCs)–A review. Atmospheric Environment, v. 140, p. 117-134, 2016.

LEE, T., KO, S. H., CHO, S. J., & RYOO, R. Ultramicroporous Carbon Synthesis Using Lithium-Ion Effect in ZSM-5 Zeolite Template. Chemistry of Materials, v. 30, n. 18, p. 6513-6520, 2018.

LI, C., ZHU, Q., CUI, Z., WANG, B., FANG, Y., & TAN, T. Highly efficient and selective production of acrylic acid from 3-hydroxypropionic acid over acidic heterogeneous catalysts. Chemical Engineering Science, v. 183, p. 288-294, 2018.

LI, T., FENG, H., WANG, Y., WANG, C., ZHU, W., YUAN, L., & ZHOU, G. Formation of modulated structures induced by oxygen vacancies in α-Fe2O3 nanowires. Journal of Crystal Growth, v. 498, p. 10-16, 2018.

LIU, N., YUAN, X., ZHANG, R., LI, Y., CHEN, B. Mechanistic insight into selective catalytic combustion of HCN over Cu-BEA: Influence of different active center structures. Physical Chemistry, v. 19, n. 35, p. 23960-23970, 2017.

LIMA C. G. S., MOREIRA N. M., PAIXÃO M. W., CORREA A. G. Heterogenous green catalysis: Application of zeolites on multicomponente reactions. Green and Sustainable Chemistry, 2018.

LIU, M., ZHAO, Y., ZHAO, H., LI, X., MA, Y., YONG, X., CHEN, H., & LI, Y. The promotion effect of nickel and lanthanum on Cu-ZSM-5 catalyst in NO direct decomposition. Catalysis Today, v. 327, p. 203-209, 2019.

MUÑOZ, R., JACINTO, M., GUIEYSSE, B., & MATTIASSON, B. Combined carbon and nitrogen removal from acetonitrile using algal–bacterial bioreactors. Applied microbiology and biotechnology, v. 67, n. 5, p. 699-707, 2005.

NAKHOSTIN PANAHI, P., SALARI, D., TSENG, H. H., NIAEI, A., & MOUSAVI, S. M. Effect of the preparation method on activity of Cu-ZSM-5 nanocatalyst for the selective reduction of NO by NH3. Environmental technology, v. 38, n. 15, p. 1852-1861, 2017.

OLIVEIRA, J. S., DRUMM, F. C., MAZUTTI, M. A., FOLETTO, E. L., & JAHN, S. L. (2016). Preparação do sistema Fe2O3/ZSM-5 para uso como catalisador na reação foto-Fenton. Cerâmica, v. 62, p. 281-287, 2016.

ROMERO-SÁEZ, M., DIVAKAR, D., ARANZABAL, A., GONZÁLEZ-VELASCO, J. R., & GONZÁLEZ-MARCOS, J. A. Catalytic oxidation of trichloroethylene over Fe-ZSM-5: Influence of the preparation method on the iron species and the catalytic behavior. Applied Catalysis B: Environmental, v. 180, p. 210-218, 2016.

SCHMAL, M. Catálise Heterogênea. Editora Synergia, 2011.

TAVARES, H. D., ANGIOLETTO, E. Síntese e estudo de propriedades catalíticas do Fe2O3 obtido do tratamento da drenagem ácida de mineração, em processos oxidativos avançados. Trabalho de conclusão de curso. Departamento de Engenharia Química, Universidade do Extremo Sul Catarinense, 2019.

WANG, Y., ZHAO, W., LI, Z., WANG, H., WU, J., LI, M., HU, Z., WANG Y., HUANG, J., & ZHAO, Y. Application of mesoporous ZSM-5 as a support for Fischer–Tropsch cobalt catalysts. Journal of Porous Materials, v. 22, n. 2, p. 339-345, 2015.

XING, X., LI, N., SUN, Y., WANG, G., CHENG, J., & HAO, Z. Selective catalytic oxidation of n-butylamine over Cu-zeolite catalysts. Catalysis Today, 2018.

YANG, M., SHAO, J., YANG, Z., YANG, H., WANG, X., WU, Z., & CHEN, H. Conversion of lignin into light olefins and aromatics over Fe/ZSM-5 catalytic fast pyrolysis: Significance of Fe contents and temperature. Journal of analytical and applied pyrolysis, v. 137, p. 259-265, 2019.

KARAKAS, G. & SEVINC, A. Catalytic oxidation of nitrogen containing compounds for nitrogen determination. Catalysis Today, v. 323, p. 159-165, 2019.

ZHANG, R., HEDJAZI, K., CHEN, B., LI, Y., LEI, Z., & LIU, N. M (Fe, Co)-BEA washcoated honeycomb cordierite for N2O direct decomposition. Catalysis Today, v. 273, p. 273-285, 2016.

ZHANG, R., SHI, D., LIU, N., CAO, Y., & CHEN, B. Mesoporous SBA-15 promoted by 3d-transition and noble metals for catalytic combustion of acetonitrile. Applied Catalysis B: Environmental, v. 146, p. 79-93, 2014.

ZHANG, R., SHI, D., LIU, N., CHEN, B., WU, L., WU, L., & YANG, W. Catalytic purification of acrylonitrile-containing exhaust gases from petrochemical industry by metal-doped mesoporous zeolites. Catalysis Today, v. 258, p. 17-27, 2015.