Construction dual active sites on confined ordered mesoporous CeWTi catalyst by CuSO4 modification for enhancing SO2 tolerance during low temperature NH3-SCR process

IF 6.7 1区 工程技术 Q2 ENERGY & FUELS Fuel Pub Date : 2024-11-28 DOI:10.1016/j.fuel.2024.133836
Mengqian Li , Xiaosheng Huang , Guodong Zhang , Zhicheng Tang , Dongcheng Hu
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Abstract

The full exposure of the active center is an important reason for the superior performance, and the excellent anti-SO2 poisoning ability is a key factor to ensure the service life for the low temperature NH3-SCR catalyst. In this study, the strategy of evaporation-induced self-assembly (EISA) was chosen to directly confined CuSO4 to the framework structure of ordered mesoporous CeWTiOx (CWT-OM) catalyst. Metal sulfate plays a dual role in low temperature activity and sulfur resistance. When the temperature reached 220 °C, the NO conversion of ordered mesoporous CuSO4/CeWTiOx (CuCWT-OM) catalyst reached about 90 %. Introduce 100 ppm SO2 17.5 h under 260 °C, the conversion of CuCWT-OM catalyst can keep the above 80 %. The introduction of CuSO4 increased the acidity of CWT-OM catalyst, inhibited the sulfate formed by the reaction of SO2 with active species, and ensured the number of active sites in the reaction. In addition, the Cu-Ce interface effect accelerates the electron transfer frequency between the active species, stimulates the production of adsorbed NO2, and promotes the conversion of NO at low temperature. Furthermore, the interface confined effect and the framework confined effect make the active species Cu and Ce firmly confined in the ordered mesoporous framework structure, and reduce the action of SO2 on the active components. In addition, SO42− is more likely to react with W species, protecting the main active species Ce and inhibiting its acidification. This work provides a new feasible idea for improving the low temperature activity and anti-SO2 poisoning stability of Ce based catalyst.

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通过 CuSO4 改性在封闭有序介孔 CeWTi 催化剂上构建双活性位点,提高低温 NH3-SCR 过程中的二氧化硫耐受性
活性中心的充分暴露是低温 NH3-SCR 催化剂性能优越的重要原因,而优异的抗二氧化硫中毒能力则是确保其使用寿命的关键因素。本研究选择了蒸发诱导自组装(EISA)的策略,将 CuSO4 直接封闭在有序介孔 CeWTiOx(CWT-OM)催化剂的框架结构中。金属硫酸盐在低温活性和抗硫性方面起着双重作用。当温度达到 220 ℃ 时,有序介孔 CuSO4/CeWTiOx (CuCWT-OM) 催化剂的氮氧化物转化率达到约 90%。在 260 °C 下引入 100 ppm SO2 17.5 h,CuCWT-OM 催化剂的转化率可保持在 80% 以上。引入 CuSO4 增加了 CWT-OM 催化剂的酸度,抑制了 SO2 与活性物种反应生成的硫酸盐,保证了反应中活性位点的数量。此外,Cu-Ce 界面效应加快了活性物种之间的电子转移频率,刺激了吸附 NO2 的产生,促进了低温下 NO 的转化。此外,界面约束效应和框架约束效应使活性物种 Cu 和 Ce 被牢固地约束在有序的介孔框架结构中,减少了 SO2 对活性成分的作用。此外,SO42- 更容易与 W 物种发生反应,从而保护主要活性物种 Ce 并抑制其酸化。这项工作为提高 Ce 基催化剂的低温活性和抗二氧化硫中毒稳定性提供了一种新的可行思路。
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来源期刊
Fuel
Fuel 工程技术-工程:化工
CiteScore
12.80
自引率
20.30%
发文量
3506
审稿时长
64 days
期刊介绍: The exploration of energy sources remains a critical matter of study. For the past nine decades, fuel has consistently held the forefront in primary research efforts within the field of energy science. This area of investigation encompasses a wide range of subjects, with a particular emphasis on emerging concerns like environmental factors and pollution.
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