Iron Particle Size Effects for Direct Production of Lower Olefins from Synthesis Gas

• Published in: Journal of the American Chemical Society Vol. 134; no. 39; pp. 16207 - 16215
• Main Authors: Torres Galvis, Hirsa M, Bitter, Johannes H, Davidian, Thomas, Ruitenbeek, Matthijs, Dugulan, A. Iulian, de Jong, Krijn P
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 03.10.2012
• ISSN: 0002-7863; 1520-5126
• DOI: 10.1021/ja304958u

The Fischer–Tropsch synthesis of lower olefins (FTO) is an alternative process for the production of key chemical building blocks from non-petroleum-based sources such as natural gas, coal, or biomass. The influence of the iron carbide particle size of promoted and unpromoted carbon nanofiber supported catalysts on the conversion of synthesis gas has been investigated at 340–350 °C, H2/CO = 1, and pressures of 1 and 20 bar. The surface-specific activity (apparent TOF) based on the initial activity of unpromoted catalysts at 1 bar increased 6–8-fold when the average iron carbide size decreased from 7 to 2 nm, while methane and lower olefins selectivity were not affected. The same decrease in particle size for catalysts promoted by Na plus S resulted at 20 bar in a 2-fold increase of the apparent TOF based on initial activity which was mainly caused by a higher yield of methane for the smallest particles. Presumably, methane formation takes place at highly active low coordination sites residing at corners and edges, which are more abundant on small iron carbide particles. Lower olefins are produced at promoted (stepped) terrace sites that are available and active, quite independent of size. These results demonstrate that the iron carbide particle size plays a crucial role in the design of active and selective FTO catalysts.