Preparation and Characterization: The Effect of Incorporation by Ion Exchange of Pt, Ni and Ru on a H-ZSM5 Zeolite

Abstract: The objective of this work was based on catalysts Pt, Ni and Ru supported on zeolite NH4ZSM-5 and characterize them. In this work monometallic bifunctional catalysts were prepared (Pt/NH4ZSM-5; Ni/NH4ZSM-5; Ru/NH4ZSM-5), all containing the same concentration of each metal supported by competitive ion exchange, using solutions of platinum complexes [Pt (NH3)4] Cl2, Nickel [Ni (NH3)6] Cl2and chloride Ruthenium III (RuCl3). The samples were characterized by chemical analysis by X-ray Spectroscopy Energy dispersiv… Show more

“…The diffraction pattern for the catalysts was similar. According to data [46,48], the presence of Pt has virtually no effect on the framework structure of the zeolite, including under ion exchange conditions. In this case, the metal was detected in the form of larger particles, in comparison with the ion exchange method [46], and one reflection in the range of 2θ ≈ 15°-20° near Co3O4 for monometallic catalysts sometimes leads to a strong metal-support interaction [46].…”

“…According to data [46,48], the presence of Pt has virtually no effect on the framework structure of the zeolite, including under ion exchange conditions. In this case, the metal was detected in the form of larger particles, in comparison with the ion exchange method [46], and one reflection in the range of 2θ ≈ 15°-20° near Co3O4 for monometallic catalysts sometimes leads to a strong metal-support interaction [46]. For the studied catalysts with Pt in the structure of the acid component and on the surface of the composite, they were accompanied by some shift of the Co3O4 reflection (hkl 3 1 1) from d = 0.244 nm at an intensity of 107 arb.…”

“…A promising option for expanding the scope of the application of the catalyst may be searching for the optimal hydrogenating metal, including Pt. The method of introducing Pt into the catalyst (using a precursor, which, according to [46], provides the highest dispersion of the metal and the best catalytic characteristics) is seen as a way to influence the state of cobalt centers as an active metal, in conjunction with the acid centers of the zeolite in the spatial structure of the catalyst. The presence of a hydrogenating agent, as a second metal in the composition of a bifunctional catalyst, should obviously be accompanied by an effect on the particle size, dispersion, crystalline orientation of cobalt and other components in the system and the occurrence of effects that depend not only on the number and proximity of metal and acid centers but also, possibly, on the number of acid sites between two metal centers.…”

The Influence of Platinum on the Catalytic Properties of Bifunctional Cobalt Catalysts for the Synthesis of Hydrocarbons from CO and H2

“…The diffraction pattern for the catalysts was similar. According to data [46,48], the presence of Pt has virtually no effect on the framework structure of the zeolite, including under ion exchange conditions. In this case, the metal was detected in the form of larger particles, in comparison with the ion exchange method [46], and one reflection in the range of 2θ ≈ 15°-20° near Co3O4 for monometallic catalysts sometimes leads to a strong metal-support interaction [46].…”

“…According to data [46,48], the presence of Pt has virtually no effect on the framework structure of the zeolite, including under ion exchange conditions. In this case, the metal was detected in the form of larger particles, in comparison with the ion exchange method [46], and one reflection in the range of 2θ ≈ 15°-20° near Co3O4 for monometallic catalysts sometimes leads to a strong metal-support interaction [46]. For the studied catalysts with Pt in the structure of the acid component and on the surface of the composite, they were accompanied by some shift of the Co3O4 reflection (hkl 3 1 1) from d = 0.244 nm at an intensity of 107 arb.…”

“…A promising option for expanding the scope of the application of the catalyst may be searching for the optimal hydrogenating metal, including Pt. The method of introducing Pt into the catalyst (using a precursor, which, according to [46], provides the highest dispersion of the metal and the best catalytic characteristics) is seen as a way to influence the state of cobalt centers as an active metal, in conjunction with the acid centers of the zeolite in the spatial structure of the catalyst. The presence of a hydrogenating agent, as a second metal in the composition of a bifunctional catalyst, should obviously be accompanied by an effect on the particle size, dispersion, crystalline orientation of cobalt and other components in the system and the occurrence of effects that depend not only on the number and proximity of metal and acid centers but also, possibly, on the number of acid sites between two metal centers.…”

The Influence of Platinum on the Catalytic Properties of Bifunctional Cobalt Catalysts for the Synthesis of Hydrocarbons from CO and H2

“…Contrary to impregnation ion exchange involves the interchange of ions from a carrier with an active metal. This method is carried out by inserting cations into zeolites through the exchange of alkali or alkaline earth cations by using precursor salts [33][34][35][36][37][38][39][40][41].…”

Catalytic Cracking of Methyl Ester from Used Cooking Oil with Ni-Ion-Exchanged ZSM-5 Catalyst

Adsorption of gaseous pollutants by alkali-activated materials