Silica-Confined Pt₃Sn Clusters for Propane Dehydrogenation

Abstract: Silica-confined Pt x Sn1–x (x = 0.6–1.0) clusters were examined for the dehydrogenation of propane to propylene, in terms of the activity and selectivity. It was found that the Pt0.8Sn0.2 cluster of 1.5 nm, encapsulated in a porous silica particle of about 20 nm, was highly active and selective, yielding propane conversion of 20% and propylene selectivity of 97% at 873 K. The specific activity, based on Pt mass, was approximately two times greater than that over the Pt cluster at a similar size. The Pt3Sn all… Show more

“…Temperature programmed reduction in hydrogen atmosphere (H 2 -TPR) and diffuse reflectance infrared Fourier transform of CO adsorption (CO-DRIFT) were further employed to illustrate the SnO x effects on the Pt-SnO x /Al 2 O 3 catalysts. The H 2 -TPR results of Pt/Al 2 O 3 and SnO x /Al 2 O 3 unveiled reduction peaks at approximately 242 and 429 °C (Figure c), corresponding to the reduction of PtO x and SnO x . , Contrarily, for three Pt-SnO x /Al 2 O 3 catalysts, the reduction peaks of PtO x occurred at a higher temperature (268 °C), while the reduction peak of SnO x appeared at a lower temperature (420 °C). This observation is attributed to the hydrogen spillover effect of Pt and the strong interaction between PtO x and SnO x species, respectively.…”

“…However, when the n Sn /n Pt ratio was further increased to 3.0, the percentage of both Sn 0 and Sn 2+ decreased due to more SnO x strongly interacted with SnO x . 48,49 Contrarily, for three Pt-SnO x /Al 2 O 3 catalysts, the reduction peaks of PtO x occurred at a higher temperature (268 °C), while the reduction peak of SnO x appeared at a lower temperature (420 °C). This observation is attributed to the hydrogen spillover effect of Pt and the strong interaction between PtO x and SnO x species, respectively.…”

“…CO–DRIFT spectra for Pt-SnO x /Al 2 O 3 catalysts exhibited similar CO adsorption patterns to Pt/Al 2 O 3 in the range of 1830 to 2100 cm –1 (Figure d). These bands are commonly assigned to the bridged-adsorbed CO on two contiguous metallic Pt 0 atoms (1838–1885 cm –1 ), linear-bonded CO on metallic nanoparticle surfaces at either well-coordinated (2086 cm –1 ) or under-coordinated (2068 cm –1 ) Pt 0 sites, and linear-bonded CO on oxidized Pt δ+ (2124 cm –1 ). − , These results indicate that all Pt-SnO x /Al 2 O 3 catalysts still exhibit the metallic Pt 0 ensembles but do not form the identifiable PtSn alloy. Notably, the intensity of adsorbed CO bands on well-coordinated Pt 0 sites become higher, while that on under-coordinated (2030–2070 cm –1 ) Pt 0 sites become lower.…”

“…Pt-Based materials exhibit outstanding catalytic activity for (transfer) hydrogenation, , C–N coupling reactions, and methanol-involved transformations. ,, However, there remains additional potential to enhance the catalytic capability of Pt catalysts for methanol-involved reactions, ,, particularly under mild (≤130 °C) and environmentally benign reaction conditions (without base additives). It is established that modifying the active metal with a second component (e.g., SnO x , − In 2 O 3 , and MoO x ) is a reliable method to enhance the catalytic efficiency of Pt-based catalysts, surpassing individual Pt catalysts in various C–H bonds activation processes (such as alkane dehydrogenation − and methanol reforming). To achieve an efficient catalyst, a series of second component-decorated Pt materials with diverse metal oxide promoters (Table , entries 1–5) and supports (Table , entries 6–10), and their catalytic performances for the direct N -methylation of quinoline ( 1a ) with methanol were also investigated.…”

SnO_x-Decorated Pt Catalysts for the Reductive N-Methylation of Quinoline with Methanol

“…Temperature programmed reduction in hydrogen atmosphere (H 2 -TPR) and diffuse reflectance infrared Fourier transform of CO adsorption (CO-DRIFT) were further employed to illustrate the SnO x effects on the Pt-SnO x /Al 2 O 3 catalysts. The H 2 -TPR results of Pt/Al 2 O 3 and SnO x /Al 2 O 3 unveiled reduction peaks at approximately 242 and 429 °C (Figure c), corresponding to the reduction of PtO x and SnO x . , Contrarily, for three Pt-SnO x /Al 2 O 3 catalysts, the reduction peaks of PtO x occurred at a higher temperature (268 °C), while the reduction peak of SnO x appeared at a lower temperature (420 °C). This observation is attributed to the hydrogen spillover effect of Pt and the strong interaction between PtO x and SnO x species, respectively.…”

“…However, when the n Sn /n Pt ratio was further increased to 3.0, the percentage of both Sn 0 and Sn 2+ decreased due to more SnO x strongly interacted with SnO x . 48,49 Contrarily, for three Pt-SnO x /Al 2 O 3 catalysts, the reduction peaks of PtO x occurred at a higher temperature (268 °C), while the reduction peak of SnO x appeared at a lower temperature (420 °C). This observation is attributed to the hydrogen spillover effect of Pt and the strong interaction between PtO x and SnO x species, respectively.…”

“…CO–DRIFT spectra for Pt-SnO x /Al 2 O 3 catalysts exhibited similar CO adsorption patterns to Pt/Al 2 O 3 in the range of 1830 to 2100 cm –1 (Figure d). These bands are commonly assigned to the bridged-adsorbed CO on two contiguous metallic Pt 0 atoms (1838–1885 cm –1 ), linear-bonded CO on metallic nanoparticle surfaces at either well-coordinated (2086 cm –1 ) or under-coordinated (2068 cm –1 ) Pt 0 sites, and linear-bonded CO on oxidized Pt δ+ (2124 cm –1 ). − , These results indicate that all Pt-SnO x /Al 2 O 3 catalysts still exhibit the metallic Pt 0 ensembles but do not form the identifiable PtSn alloy. Notably, the intensity of adsorbed CO bands on well-coordinated Pt 0 sites become higher, while that on under-coordinated (2030–2070 cm –1 ) Pt 0 sites become lower.…”

“…Pt-Based materials exhibit outstanding catalytic activity for (transfer) hydrogenation, , C–N coupling reactions, and methanol-involved transformations. ,, However, there remains additional potential to enhance the catalytic capability of Pt catalysts for methanol-involved reactions, ,, particularly under mild (≤130 °C) and environmentally benign reaction conditions (without base additives). It is established that modifying the active metal with a second component (e.g., SnO x , − In 2 O 3 , and MoO x ) is a reliable method to enhance the catalytic efficiency of Pt-based catalysts, surpassing individual Pt catalysts in various C–H bonds activation processes (such as alkane dehydrogenation − and methanol reforming). To achieve an efficient catalyst, a series of second component-decorated Pt materials with diverse metal oxide promoters (Table , entries 1–5) and supports (Table , entries 6–10), and their catalytic performances for the direct N -methylation of quinoline ( 1a ) with methanol were also investigated.…”

SnO_x-Decorated Pt Catalysts for the Reductive N-Methylation of Quinoline with Methanol

“…Catalytic propane dehydrogenation (PDH) is a well-known reaction to produce propylene, which can be used as a precursor for a wide variety of plastic products and other value-added chemicals and has been studied for many years. Many catalysts can activate this reaction, for example, metal-based catalysts like Pt, Pd, and Ni; metal oxide-based catalysts like CrO x , VO x , GaO x , SnO x , ZrO 2 , and MoO x ; and other formulations like metal sulfides, carbides, nitrides, and carbon-based materials. − However, these catalysts have their weaknesses, for example, elevated costs in the case of noble metals, high toxicity in the case of Cr, fast coking-related deactivation in strong acid catalysts, irreversible deactivation because of the loss of sulfur in metal sulfide catalysts, and undesired hydrogenolysis as a side reaction in the metal catalysts. − Hence, many research interests are focused on developing and exploring new catalysts with high efficiency, low cost, and environmental friendliness. One of them is a silica-supported tin oxide catalyst, which shows impressive stability as a distinctive point.…”

Influence of Thermal Cracking on Propylene Selectivity in Catalytic Propane Dehydrogenation Using SnO_x–SiO₂ Catalyst

Porous silica nano-flowers stabilized Pt–Pd bimetallic nanoparticles as heterogeneous catalyst for efficiently synthesizing guaiacol from 2-methoxycyclohexanol