Abstract
Diesel engines are important for heavy-duty vehicles. However, particulate matter (PM) released from diesel exhaust should be eliminated. Nowadays, catalytic diesel particulate filters (CDPF) are recognized as a promising technology. In this work, a series of monolith Mn1−nKnCo2O4 catalysts were prepared by the simple citric acid method. The as-prepared catalysts displayed good catalytic performance for soot combustion and the Mn0.7K0.3Co2O4 catalyst gave the best catalytic performance among all the prepared samples. The T10 and Tm of Mn0.7K0.3Co2O4-HC catalyst for soot combustion are 310 and 439 °C, respectively. The physical and chemical properties of catalysts were characterized by means of SEM, XPS, H2-TPR, Raman and other techniques. The characterization results indicate that K substitution is favorable for the formation of oxygen vacancies, enhancing the mobility of active oxygen species, and improving the redox properties and so on. In-situ Raman results prove that the strength of Co-O bonds in the catalysts became weak during the reaction at high temperatures. In addition, SEM and ultrasonic test results show that the peeling rate of the coat-layer is less than 5%. The as-prepared catalysts can be taken as one kind of candidate catalyst for promising application in soot combustion because of its facile synthesis, low cost and high catalytic activity.
Highlights
IntroductionDiesel engines with excellent fuel efficiency have become the first choice for heavyduty vehicles [1,2]
Because carbon is the main component of particulate matter (PM) in diesel exhaust and its initiation temperature is higher than 450 ◦ C, PM cannot be eliminated in the temperature range of diesel exhaust (150–450 ◦ C) [4]
H2 -TPR and soot-TPR demonstrate that the mobility of active oxygen is enhanced and many more active oxygen species can participate in soot combustion than that of the
Summary
Diesel engines with excellent fuel efficiency have become the first choice for heavyduty vehicles [1,2]. Particulate matter (PM) released from diesel exhaust always threatens human health and environmental safety [3]. Because carbon is the main component of PM in diesel exhaust and its initiation temperature is higher than 450 ◦ C, PM cannot be eliminated in the temperature range of diesel exhaust (150–450 ◦ C) [4]. As the national emission standards become more stringent, it is necessary to develop catalytic purification technology to resolve the PM pollution. Catalytic diesel particulate filters (CDPF) are considered a promising technology [5]. The design and preparation of high efficiency catalysts is still a difficult problem for the practical application of CDPF. Facile Preparation of Ordered Mesoporous MnCo2 O4 for Low-Temperature Selective. Fabrication of Spinel-Type PdxCo3−x O4 Binary Active Sites on
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