Morphology Dependent Catalytic Activity of Mn3O4 for Complete Oxidation of Toluene and Carbon Monoxide

Manganese oxide catalysts having pure hausmanite (Mn 3 O 4 ) phase but different morphologies were synthesized using three different facile methods namely precipitation method (MPM), reduction method (MRM) and solution combustion method (MSM). In spite of having the same phase, their catalytic activ...

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Veröffentlicht in:	Catalysis letters 2021, Vol.151 (1), p.172-183
Hauptverfasser:	Pulleri, Jayasree K., Singh, Sunit Kumar, Yearwar, Divya, Saravanan, Govindachetty, Al-Fatesh, Ahmed Sadeq, Labhasetwar, Nitin K.
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Sprache:	eng
Schlagworte:	Carbon monoxide Catalysis Catalysts Catalytic activity Catalytic oxidation Chemical precipitation Chemical synthesis Chemistry Chemistry and Materials Science Crystallites Industrial Chemistry/Chemical Engineering Manganese oxides Morphology Organometallic Chemistry Oxidation Physical Chemistry Reduction Thermal stability Toluene
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creator	Pulleri, Jayasree K. Singh, Sunit Kumar Yearwar, Divya Saravanan, Govindachetty Al-Fatesh, Ahmed Sadeq Labhasetwar, Nitin K.
description	Manganese oxide catalysts having pure hausmanite (Mn 3 O 4 ) phase but different morphologies were synthesized using three different facile methods namely precipitation method (MPM), reduction method (MRM) and solution combustion method (MSM). In spite of having the same phase, their catalytic activities showed strong dependence on their morphologies. Mn 3 O 4 synthesized using the reduction method had a 3D framework of interconnected hexagonal crystallites. Consequently, it showed the best activity among the synthesized and commercial Mn 3 O 4 catalysts both for carbon monoxide and toluene oxidation. This superior activity of MRM was correlated to its uniform pores and ability to desorb oxygen adspecies easily due to its morphology. The catalytic oxidation activity of this catalyst was not significantly affected at high space velocities. Thermal stability of the best performing catalyst was demonstrated through its stable cyclic performance, both for carbon monoxide and toluene oxidation. Graphic Abstract
doi_str_mv	10.1007/s10562-020-03278-w
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In spite of having the same phase, their catalytic activities showed strong dependence on their morphologies. Mn 3 O 4 synthesized using the reduction method had a 3D framework of interconnected hexagonal crystallites. Consequently, it showed the best activity among the synthesized and commercial Mn 3 O 4 catalysts both for carbon monoxide and toluene oxidation. This superior activity of MRM was correlated to its uniform pores and ability to desorb oxygen adspecies easily due to its morphology. The catalytic oxidation activity of this catalyst was not significantly affected at high space velocities. Thermal stability of the best performing catalyst was demonstrated through its stable cyclic performance, both for carbon monoxide and toluene oxidation. 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In spite of having the same phase, their catalytic activities showed strong dependence on their morphologies. Mn 3 O 4 synthesized using the reduction method had a 3D framework of interconnected hexagonal crystallites. Consequently, it showed the best activity among the synthesized and commercial Mn 3 O 4 catalysts both for carbon monoxide and toluene oxidation. This superior activity of MRM was correlated to its uniform pores and ability to desorb oxygen adspecies easily due to its morphology. The catalytic oxidation activity of this catalyst was not significantly affected at high space velocities. Thermal stability of the best performing catalyst was demonstrated through its stable cyclic performance, both for carbon monoxide and toluene oxidation. Graphic Abstract</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s10562-020-03278-w</doi><tpages>12</tpages></addata></record>
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subjects	Carbon monoxide Catalysis Catalysts Catalytic activity Catalytic oxidation Chemical precipitation Chemical synthesis Chemistry Chemistry and Materials Science Crystallites Industrial Chemistry/Chemical Engineering Manganese oxides Morphology Organometallic Chemistry Oxidation Physical Chemistry Reduction Thermal stability Toluene
title	Morphology Dependent Catalytic Activity of Mn3O4 for Complete Oxidation of Toluene and Carbon Monoxide
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