Aqueous-Phase Preparation of Model HDS Catalysts on Planar Alumina Substrates: Support Effect on Mo Adsorption and Sulfidation

详细信息    查看全文

• 作者：Cédric Bara ; Lucie Plais ; Kim Larmier ; Elodie Devers ; Mathieu Digne ; Anne-Félicie Lamic-Humblot ; Gerhard D. Pirngruber ; Xavier Carrier
• 刊名：Journal of the American Chemical Society
• 出版年：2015
• 出版时间：December 23, 2015
• 年：2015
• 卷：137
• 期：50
• 页码：15915-15928
• 全文大小：897K
• ISSN：1520-5126

文摘

The role of the oxide support on the structure of the MoS₂ active phase (size, morphology, orientation, sulfidation ratio, etc.) remains an open question in hydrotreating catalysis and biomass processing with important industrial implications for the design of improved catalytic formulations. The present work builds on an aqueous-phase surface-science approach using four well-defined α-alumina single crystal surfaces (C (0001), A (112?0), M (101?0), and R (11?02) planes) as surrogates for γ-alumina (the industrial support) in order to discriminate the specific role of individual support facets. The reactivity of the various surface orientations toward molybdenum adsorption is controlled by the speciation of surface hydroxyls that determines the surface charge at the oxide/water interface. The C (0001) plane is inert, and the R (11?02) plane has a limited Mo adsorption capacity while the A (112?0) and M (101?0) surfaces are highly reactive. Sulfidation of model catalysts reveals the highest sulfidation degree for the A (112?0) and M (101?0) planes suggesting weak metal/support interactions. Conversely, a low sulfidation rate and shorter MoS₂ slabs are found for the R (11?02) plane implying stronger Mo–O–Al bonds. These limiting cases are reminiscent of type I/type II MoS₂ nanostructures. Structural analogies between α- and γ- alumina surfaces allow us to bridge the material gap with real Al₂O₃-supported catalysts. Hence, it can be proposed that Mo distribution and sulfidation rate are heterogeneous and surface-dependent on industrial γ-Al₂O₃-supported high-surface-area catalysts. These results demonstrate that a proper control of the γ-alumina morphology is a strategic lever for a molecular-scale design of hydrotreating catalysts.