Bridging the structural gap of supported vanadium oxides for oxidative dehydrogenation of propane with carbon dioxide†

EES catalysis Pub Date : 2024-06-14 DOI:10.1039/D4EY00094C
Li Wang, Heng-Bo Zhang, Rongrong Hu, Han-Qing Ge, Yong-Hong Song, Guo-Qing Yang, Yuefeng Li, Zhao-Tie Liu and Zhong-Wen Liu
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Abstract

As an extensively used industrial catalyst for oxidation reactions, supported vanadium oxide (VOx) is a promising candidate for oxidative dehydrogenation of propane with carbon dioxide (CO2-ODP). Although the structure of VOx is found to be a key factor in determining the catalytic activity and stability of supported VOx for CO2-ODP, the essential reason still remains elusive at the molecular level. To shed some light on this fundamental issue, VOx/(−)SiO2 catalysts with narrow distributions of V loading while well-defined structures of VOx species, i.e., monomeric VOx, less polymeric VOx, highly polymeric VOx and V2O5 crystallites, were purposely synthesized by appropriate methods, including one-pot hydrothermal synthesis, incipient wetness impregnation and physical grinding. We found that the catalytic activity and stability of VOx species decrease in the order of monomeric VOx > less polymeric VOx > highly polymeric VOx > crystalline V2O5, which coincides with the ability for the re-oxidation of the correspondingly reduced VOx species by CO2. As a result of the most facile re-oxidation of the reduced monomeric VOx species by CO2, a well matched redox cycle of V5+/V4+ oxides during CO2-ODP can be maintained with increasing the time on stream, leading to an improved stability of the catalyst with more monomeric VOx. These mechanistic findings on the redox properties of VOx with different structures can be guidelines for developing a high-performance VOx-based catalyst for CO2-ODP.

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缩小支撑钒氧化物在丙烷与二氧化碳氧化脱氢过程中的结构差距
作为一种广泛用于氧化反应的工业催化剂,支撑型氧化钒(VOx)是丙烷与二氧化碳的氧化脱氢反应(CO2-ODP)的理想候选催化剂。尽管人们发现氧化钒的结构是决定支撑型氧化钒在 CO2-ODP 催化活性和稳定性的关键因素,但在分子水平上,其根本原因仍然难以捉摸。为了揭示这一基本问题,我们采用适当的方法,包括一锅水热合成、初湿浸渍和物理研磨,特意合成了V载量分布较窄,而VOx物种结构明确的VOx/(-)SiO2催化剂,即单体VOx、低聚合VOx、高聚合VOx和V2O5晶体。我们发现,VOx 物种的催化活性和稳定性按照单体 VOx > 少聚合 VOx > 高聚合 VOx > 结晶 V2O5 的顺序依次降低,这与相应的还原 VOx 物种被 CO2 再氧化的能力相吻合。由于还原的单质 VOx 物种最容易被 CO2 再氧化,因此在 CO2-ODP 氧化还原过程中,V5+/V4+ 氧化物的氧化还原循环可以随着气流时间的增加而保持良好的匹配,从而提高了催化剂的稳定性,使其具有更多的单质 VOx。这些关于不同结构 VOx 氧化还原特性的机理研究结果可作为开发用于 CO2-ODP 的高性能 VOx 基催化剂的指导方针。
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Back cover Correction: High photocatalytic yield in the non-oxidative coupling of methane using a Pd–TiO2 nanomembrane gas flow-through reactor Embedding the intermetallic Pt5Ce alloy in mesopores through Pt–C coordination layer interactions as a stable electrocatalyst for the oxygen reduction reaction† Efficient CO2-to-CO conversion in dye-sensitized photocatalytic systems enabled by electrostatically-driven catalyst binding† Green energy driven methane conversion under mild conditions
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