Methane Catalytic Combustion over Hierarchical Pd@CeO2/Si‐Al2O3: Effect of the Presence of Water

Monai, Matteo; Montini, Tiziano; Chen, Chen; Fonda, Emiliano; Gorte, Raymond J.; Fornasiero, Paolo

doi:10.1002/cctc.201402717

Cited by 100 publications

(63 citation statements)

References 49 publications

(81 reference statements)

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“…3. As reported previously [8,9], Pd@CeO 2 /Si-Al 2 O 3 catalysts calcined at 773 K deactivate rapidly in the WGS environment due to reduction of the ceria, which in turn causes a loss in the CO adsorption uptakes on Pd, probably due to the ceria shell closing up around the Pd [23]. This is shown in Fig.…”

Section: Wgs Activitymentioning

confidence: 56%

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A comparison of hierarchical Pt@CeO2/Si–Al2O3 and Pd@CeO2/Si–Al2O3

et al. 2015

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a b s t r a c tA comparison of catalytic and adsorption properties for Pt@CeO 2 /Si-Al 2 O 3 (1-wt% Pt and 9-wt% CeO 2 ) and Pd@CeO 2 /Si-Al 2 O 3 (1-wt% Pd and 9-wt% CeO 2 ) core-shell catalysts indicates that the CeO 2 shell is stable for Pd but not for Pt. Following calcination at 773 K, Pt@CeO 2 /Si-Al 2 O 3 exhibits water-gas-shift (WGS) rates in 3% H 2 O and CO that are similar to rates found on conventional Pt/CeO 2 , implying that there is good contact between the Pt and CeO 2 phases, even at the relatively low CeO 2 loading. WGS rates on Pt@CeO 2 /Si-Al 2 O 3 were also reasonably stable with time and unaffected by pre-reduction of the catalyst. By comparison, WGS rates over Pd@CeO 2 /Si-Al 2 O 3 declined rapidly due to reduction of CeO 2 and were suppressed by pre-reduction of CeO 2 . After calcination to 1073 K, large metal particles were observed with Pt@CeO 2 /Si-Al 2 O 3 , but not on Pd@CeO 2 /Si-Al 2 O 3 . Coulometric titration measurements on these two materials suggest stronger interactions between CeO 2 and Pd and these are likely responsible for the higher stability of the core-shell structure in Pd@CeO 2 compared to Pd@CeO 2 .

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Section: Wgs Activitymentioning

confidence: 56%

“…Reduction of the Pd@CeO 2 /Si-Al 2 O 3 occurred gradually with decreasing P(O 2 ). Since spectroscopic data showed that the Pd in these catalysts is easily oxidized to PdO [23], the results in Fig. 4B imply that the PdO and CeO 2 reduction occur together.…”

Section: Wgs Activitymentioning

confidence: 91%

A comparison of hierarchical Pt@CeO2/Si–Al2O3 and Pd@CeO2/Si–Al2O3

et al. 2015

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“…Methane conversion over 5P5C-SCS increased with increasing operating temperature with full conversion attained at around 410 • C. It was worth noticing that under similar reaction conditions, complete combustion of methane over conventional 5P-I and 5P5C-I catalysts was never achieved. Secondly, contrary to the conventional 5P-I and 5P5C-I catalysts, the 5P5C-SCS nanocatalyst exhibited superior activity with no sign of deactivation in the temperature range betweeñ 400 and 800 • C. This behavior of the SCS catalysts resembled the core shell catalysts that have made a breakthrough in methane oxidation research [25,34]. On the other hand, the SCS catalysts were superior to the traditional catalysts which all showed significant deactivation at high temperature [15,19,20].…”

Section: Catalytic Activitymentioning

confidence: 88%

“…The adsorption of O 2 on oxygen vacancies, presumably followed by its dissociation is expected to play a major role in the oxidation reaction. It is generally accepted that the prevalent mechanism of the high temperature CH 4 catalytic oxidation involves a redox Mars-van Krevelen-type reaction [20,34,66]. In the present catalysts, the point of interaction between Pd and CeO 2 and/or the intrinsic oxygen vacancies presumably acted as centers for dissociating molecular oxygen into chemisorbed oxygen (O*) which were then consumed in the oxidation reaction.…”

Section: Catalytic Activitymentioning

confidence: 98%

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Active and Stable Methane Oxidation Nano-Catalyst with Highly-Ionized Palladium Species Prepared by Solution Combustion Synthesis

et al. 2018

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We report on the synthesis and testing of active and stable nano-catalysts for methane oxidation. The nano-catalyst was palladium/ceria supported on alumina prepared via a one-step solution-combustion synthesis (SCS) method. As confirmed by X-ray photoelectron spectroscopy (XPS) and high-resolution transmission electron microscopy (HTEM), SCS preparative methodology resulted in segregating both Pd and Ce on the surface of the Al 2 O 3 support. Furthermore, HTEM showed that bigger Pd particles (5 nm and more) were surrounded by CeO 2 , resembling a core shell structure, while smaller Pd particles (1 nm and less) were not associated with CeO 2 . The intimate Pd-CeO 2 attachment resulted in insertion of Pd ions into the ceria lattice, and associated with the reduction of Ce 4+ into Ce 3+ ions; consequently, the formation of oxygen vacancies. XPS showed also that Pd had three oxidation states corresponding to Pd 0 , Pd 2+ due to PdO, and highly ionized Pd ions (Pd (2+x)+ ) which might originate from the insertion of Pd ions into the ceria lattice. The formation of intrinsic Ce 3+ ions, highly ionized (Pd 2+ species inserted into the lattice of CeO 2 ) Pd ions (Pd (2+x)+ ) and oxygen vacancies is suggested to play a major role in the unique catalytic activity. The results indicated that the Pd-SCS nano-catalysts were exceptionally more active and stable than conventional catalysts. Under similar reaction conditions, the methane combustion rate over the SCS catalyst was~18 times greater than that of conventional catalysts. Full methane conversions over the SCS catalysts occurred at around 400 • C but were not shown at all with conventional catalysts. In addition, contrary to the conventional catalysts, the SCS catalysts exhibited superior activity with no sign of deactivation in the temperature range between~400 and 800 • C.

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Recent Progress in Well‐Controlled Synthesis of Ceria‐Based Nanocatalysts towards Enhanced Catalytic Performance

Sun

Yan

2016

Advanced Energy Materials

121

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The unique electronic configuration and structural properties of ceria make ceria‐based nanomaterials such as morphology‐dependent ceria nanocrystals, rare earth‐doped ceria‐zirconia solid solutions and noble metal‐ceria nanocomposites effective promoters in three‐way catalysts for low‐temperature water‐gas‐shift reaction, preferential oxidation of traces of CO, the treatment of toxic auto‐mobile exhaust, etc. The activities of nanoceria catalysts can be determined by their morphologies, oxygen vacancies, interfacial structures and the type of exposed crystal surfaces, as well as the synergistic effect exhibited by nanocomposites. In this review, the state‐of‐the‐art developments in the well‐controlled synthesis of ceria‐based nanocatalysts and their applications in both environmental and energy fields is summarized. The involved reaction mechanisms are also briefly introduced, and eventually an outlook in the design of novel nanoceria catalysts for valuable energy applications is addressed.

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Methane Catalytic Combustion over Hierarchical Pd@CeO₂/Si‐Al₂O₃: Effect of the Presence of Water

Cited by 100 publications

References 49 publications

A comparison of hierarchical Pt@CeO2/Si–Al2O3 and Pd@CeO2/Si–Al2O3

A comparison of hierarchical Pt@CeO2/Si–Al2O3 and Pd@CeO2/Si–Al2O3

Active and Stable Methane Oxidation Nano-Catalyst with Highly-Ionized Palladium Species Prepared by Solution Combustion Synthesis

Recent Progress in Well‐Controlled Synthesis of Ceria‐Based Nanocatalysts towards Enhanced Catalytic Performance

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