通过控制碳化时间在 Mo2C/AC 上将 NO2 高效转化为 NO

IF 1.3 4区化学 Q4 CHEMISTRY, PHYSICAL Kinetics and Catalysis Pub Date : 2024-08-15 DOI:10.1134/S0023158423601067

Shifang Mu, Yan Wang, Hongliang Wang, Yujing Weng, Qi Sun, Yulong Zhang

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引用次数: 0

摘要

摘要以硝酸预处理过的活性碳（AC）为载体制备了 Mo2C/AC-x 转化器，x 代表碳化时间。在固定床反应器中对该转化器将二氧化氮转化为氮氧化物的性能进行了评估。通过 X 射线衍射（XRD）、扫描电子显微镜（SEM）、N2 物理吸附和解吸、H2 程序温度还原（H2-TPR）和 NO2 温度程序解吸质谱（NO2 TPD-MS）对 Mo2C/AC-x 转化器进行了表征。NO2 到 NO 的转化率按以下顺序降低：Mo2C/AC-4；Mo2C/AC-2；Mo2C/AC-6；Mo2C/AC-0.5。碳化时间短（如 0.5 小时）会导致 MoO2 不完全碳化为 β-Mo2C。相反，碳化时间过长（如 6 小时）则会形成碳沉积，堵塞孔隙或覆盖活性位点，导致催化性能下降。Mo2C/AC-4 的比表面积和孔体积最大。在 150°C 时，Mo2C/AC-4 的二氧化氮转化率达到 98.9%，这表明在较低温度下二氧化氮可直接有效地转化为二氧化氮。

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Efficient Conversion of NO2 to NO over Mo2C/AC by Controlling Carbonization Time

Mo₂C/AC-x converters were prepared using nitric acid pretreated activated carbon (AC) as a carrier, with x representing the carbonization time. The performance of the converter in converting NO₂ to NO was evaluated in a fixed bed reactor. The Mo₂C/AC-x converters were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), N₂ physisorption and desorption, H₂ programmed temperature reduction (H₂-TPR) and NO₂ temperature-programmed desorption–mass spectrometry (NO₂ TPD-MS). The NO₂ to NO conversion rate decreases in the following order: Mo₂C/AC-4 > Mo₂C/AC-2 > Mo₂C/AC-6 > Mo₂C/AC-0.5. Short carbonization times, like 0.5 h, led to incomplete carbonization of MoO₂ to β-Mo₂C. Conversely, long carbonization times, like 6 h, resulted in the formation of carbon deposits that can block pores or cover active sites, leading to decreased catalytic performance. Mo₂C/AC-4 has the highest specific surface area and pore volume. The NO₂ conversion rate of Mo₂C/AC-4 reached 98.9% at 150°C, demonstrating direct efficient conversion of NO₂ to NO at a lower temperature.

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来源期刊

Kinetics and Catalysis 化学-物理化学

CiteScore

2.10

自引率

27.30%

发文量

审稿时长

6-12 weeks

期刊介绍： Kinetics and Catalysis Russian is a periodical that publishes theoretical and experimental works on homogeneous and heterogeneous kinetics and catalysis. Other topics include the mechanism and kinetics of noncatalytic processes in gaseous, liquid, and solid phases, quantum chemical calculations in kinetics and catalysis, methods of studying catalytic processes and catalysts, the chemistry of catalysts and adsorbent surfaces, the structure and physicochemical properties of catalysts, preparation and poisoning of catalysts, macrokinetics, and computer simulations in catalysis. The journal also publishes review articles on contemporary problems in kinetics and catalysis. The journal welcomes manuscripts from all countries in the English or Russian language.