Abstract: The invention relates to catalyst compositions and components thereof for use in a catalytic process, and more particularly in a catalytic pyrolysis process or gasification of solid biomass material. In one aspect, a catalyst component is provided. The catalyst component includes a hybrid silica-alumina having a controlled Lewis acidity, and having a controlled porosity providing optimized accessibility for reactants.

Abstract: A catalyst composition comprising about 5–55 wt % metal-doped anionic clay, about 10–50 wt % zeolite, about 5–40 wt % matrix alumina, about 0–10 wt % silica, about 0–10 wt % of other ingredients, and balance kaolin. In metal-doped anionic clays, the additive, i.e. the metal dopant, is distributed more homogeneously within the anionic clay than in impregnated anionic clays, without separate phases of additive being present. Hence, abrasion of this catalyst composition will result in microfines poorer in additive than the prior art composition. Furthermore, the catalyst composition according to the invention results in a higher reduction of sulfur in fuels such as gasoline and diesel than is the case in compositions comprising impregnated anionic clay.

Abstract: A catalyst composition comprising about 5-55 wt % metal-doped anionic clay, about 10-50 wt % zeolite, about 5-40 wt % matrix alumina, about 0-10 wt % silica, about 0-10 wt % of other ingredients, and balance kaolin. In metal-doped anionic clays, the additive, i.e. the metal dopant, is distributed more homogeneously within the anionic clay than in impregnated anionic clays, without separate phases of additive being present. Hence, abrasion of this catalyst composition will result in microfines poorer in additive than the prior art composition. Furthermore, the catalyst composition according to the invention results in a higher reduction of sulfur in fuels such as gasoline and diesel than is the case in compositions comprising impregnated anionic clay.