高分散还原态Pt基催化剂的制备及其NO氧化的催化性能

doi:10.3866/PKU.WHXB202005009

Abstract

Abstract:

Pt-based catalysts are widely used in diesel oxidation catalyst (DOC) units, primarily to oxidize the harmful HC, CO, and NO emissions. Notably, NO₂ produced from NO oxidation is beneficial for low-temperature activity in NH₃-SCR and promotes soot oxidation in diesel particulate filters (DPF). Thus, the conversion of NO is an important parameter for determining the performance of DOCs. Considering the increasingly stringent emission regulations and the economic effectiveness, preparation of low-cost and highly active Pt-based catalysts is indispensable. Generally, the Pt⁰ content is crucial as it is an active component of DOCs. Small Pt size is beneficial for improving the catalytic activity. In this study, we applied a modified alcohol reduction-impregnation (MARI) method to synthesize highly active 1% (w, mass fraction) Pt/SiO₂-Al₂O₃ (denoted as MA-Pt/SA) catalyst. Meanwhile, using the conventional impregnation method, we prepared the Pt/SiO₂-Al₂O₃ catalyst with the same Pt loading (denoted as C-Pt/SA) as a reference sample. X-ray photoelectron spectroscopy (XPS) and hydrogen temperature program reduction (H₂-TPR) analyses proved that the MARI method could produce Pt catalysts with higher Pt⁰ content. Pt⁰ content in MA-Pt/SA was ~60.3% while that in C-Pt/SA was only ~23.1%. X-ray diffraction (XRD), CO-diffuse reflectance infrared Fourier transform spectroscopy (CO-DRIFTS), and transmission electron microscopy (TEM) characterization confirmed that the Pt particle size is much smaller over MA-Pt/SA as compared to that over C-Pt/SA. Performance evaluation of MA-Pt/SA and C-Pt/SA was conducted in a simulated diesel atmosphere. The results showed that the maximum NO conversion into NO₂ over MA-Pt/SA is 74% and 68% in the absence and presence of H₂O, respectively, which were much higher than those over C-Pt/SA (42% and 51% NO conversion with and without H₂O, respectively). Furthermore, the temperature for 30% NO conversion over MA-Pt/SA (218 ℃) markedly decreased as compared to that over C-Pt/SA (248 ℃), indicating the excellent low temperature activity. After the aging treatment with reaction gas at high temperatures, aged MA-Pt/SA maintained 69% NO conversion while aged C-Pt/SA showed only 41% NO conversion. In addition, in situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) of NO + O₂ co-adsorption suggested that higher Pt dispersion and higher Pt⁰ content over MA-Pt/SA could facilitate the formation of bridging nitrates as intermediate species in NO oxidation at lower temperatures and could also facilitate their rapid decomposition (or desorption) at higher temperatures, thus imparting a high catalytic activity. Furthermore, a decrease in the Pt loading to 0.5% (w) resulted in a maximum NO conversion of 64% via the MARI method, suggesting a higher catalytic activity compared to that of C-Pt/SA with 1% (w) Pt loading. This work provides a method to prepare highly active Pt-based catalysts with low noble loading.

Key words: DOC, Modified alcohol reduction-impregnation method, NO oxidation, High-performing Pt catalyst, Low Pt loading

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Xinmei Ding, Yanli Liang, Hailong Zhang, Ming Zhao, Jianli Wang, Yaoqiang Chen. Preparation of Reduced Pt-Based Catalysts with High Dispersion and Their Catalytic Performances for NO Oxidation[J].Acta Phys. -Chim. Sin., 2022, 38(4): 2005009.

Figures/Tables 13

References 49

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Sample	Relative area ratio (%)
Sample	Pt⁰	Pt²⁺	Pt⁴⁺
C-Pt/SA-f	23.1	41.9	35.0
MA-Pt/SA-f	60.3	17.8	21.9

Catalyst	Pt size (nm)	Pt dispersion^c (%)	T₅₀/T₉₀ (℃)		NO Max conversion (%)	Temperature (℃) ^d	TOF (s^-1)
Catalyst	Pt size (nm)	Pt dispersion^c (%)	CO	HC	NO Max conversion (%)	Temperature (℃) ^d	TOF (s^-1)
C-Pt/SA-f	27.5^a/7.8 ^b	14.5	221/236	229/237	51	248	0.06^e
MA-Pt/SA-f	8.2^a/3.8 ^b	29.6	197/209	208/212	74	218	0.22^e
C-Pt/SA-a	34.1^a/9.2 ^b	12.3	233/248	245/253	41	278	0.03^f
MA-Pt/SA-a	9.5^a/5.1 ^b	22.0	204/217	215/222	69	226	0.21^f

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Preparation of Reduced Pt-Based Catalysts with High Dispersion and Their Catalytic Performances for NO Oxidation

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