The Catalytic Performance of CO Oxidation over MnOx-ZrO2 Catalysts: The Role of Synthetic Routes

The Catalytic Performance of CO Oxidation over MnOx-ZrO2 Catalysts: The Role of Synthetic Routes Научная публикация

Журнал

Catalysts
, E-ISSN: 2073-4344

Вых. Данные

Год: 2023, Том: 13, Номер: 1, Номер статьи : 57, Страниц : 16 DOI: 10.3390/catal13010057

Ключевые слова

catalyst; CO oxidation; manganese oxide; fluorite; solid solution; zirconia

Авторы

Bulavchenko Olga A. ^1,2 , Konovalova Valeriya P. ^1,2 , Saraev Andrey A. ^1,2 , Kremneva Anna M. ¹ , Rogov Vladimir A. ^1,2 , Gerasimov Evgeny Yu. ^1,2 , Afonasenko Tatyana N. ³

Организации

1	Boreskov Institute of Catalysis SB RAS, Lavrentiev Ave., 5, Novosibirsk 630090, Russia
2	Department of Physics, Novosibirsk State University, Pirogova, 2, Novosibirsk 630090, Russia
3	Center of New Chemical Technologies, Boreskov Institute of Catalysis, Neftezavodskaya 54, Omsk 644040, Russia

Информация о финансировании (1)

Министерство науки и высшего образования Российской Федерации

075‐15‐2022‐263

MnOx‐ZrO2 catalysts prepared by co‐precipitation and vacuum impregnation were calcined at 400–800 °C and characterized by powder X‐ray diffraction, textural studies, high‐resolution transmission electron microscopy, temperature‐programmed reduction, X‐ray absorption near edge structure, and X‐ray photoelectron spectroscopy. The catalytic activity was tested in the CO oxidation reaction. The activity of the co‐precipitated samples exceeds that of the catalysts prepared by vacuum impregnation. The characterization studies showed that the nature of the active component for the catalysts obtained by co‐precipitation differs from that of the catalysts obtained by impregnation. In the impregnation series, the most active catalyst was obtained at a temperature of 400 °С; its increased activity is due to the formation of MnO2 oxide nanoparticles containing Mn4+ and lowtemperature reducibility. An increase in the synthesis temperature leads to the formation of less active Mn2O3, catalyst sintering, and, accordingly, deterioration of the catalytic properties. In the case of co‐precipitation, the most active CO oxidation catalysts are formed by calcination at 650–700 °C in air. In this temperature interval, on the one hand, a MnyZr1‐yO2‐x solid solution is formed, and on the other hand, a partial separation of mixed oxide begins with the formation of highly dispersed and active MnOx. A further increase in temperature to 800 °C leads to complete decomposition of the solid solution, the release of manganese cations into Mn3O4, and a drop in catalytic activity.

Bulavchenko O.A. , Konovalova V.P. , Saraev A.A. , Kremneva A.M. , Rogov V.A. , Gerasimov E.Y. , Afonasenko T.N.
The Catalytic Performance of CO Oxidation over MnOx-ZrO2 Catalysts: The Role of Synthetic Routes
Catalysts. 2023. V.13. N1. 57 :1-16. DOI: 10.3390/catal13010057 WOS Scopus РИНЦ OpenAlex

Поступила в редакцию:	14 нояб. 2022 г.
Принята к публикации:	23 дек. 2022 г.
Опубликована online:	27 дек. 2022 г.
Опубликована в печати:	1 янв. 2023 г.

Web of science:	WOS:000914727400001
Scopus:	2-s2.0-85146705500
РИНЦ:	53957566
OpenAlex:	W4312224699

БД	Цитирований
Web of science	3
OpenAlex	6
Scopus	6