Trapping of Mobile Pt Species by PdO Nanoparticles under Oxidizing Conditions

Carrillo, Cristihan; Johns, Tyne R.; Xiong, Haifeng; DeLaRiva, Andrew; Challa, Sivakumar R.; Goeke, Ronald S.; Artyushkova, Kateryna; Li, Wei; Kim, Chang Hwan; Datye, Abhaya K.

doi:10.1021/jz5009483

Cited by 82 publications

(66 citation statements)

References 12 publications

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“…As expected, [39] the addition of palladium to platinum preventedi ts excessive sintering, which also can be seen in the TEM images of the calcined catalysts ( Figure 1). Ar icher palladium content of the catalysts resultsi nal ower degree of sintering.…”

Section: Resultssupporting

confidence: 81%

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al₂O₃: An In Situ X‐ray Absorption Study

Nassiri

Lee

et al. 2016

ChemPhysChem

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Palladium-platinum bimetallic catalysts supported on alumina with palladium/platinum molar ratios ranging from 0.25 to 4 are studied in dry lean methane combustion in the temperature range of 200 to 500 °C. Platinum addition decreases the catalyst activity, which cannot be explained by the decrease in dispersion or the structure sensitivity of the reaction. In situ X-ray absorption near-edge structure and extended X-ray absorption fine structure spectroscopy measurements have been conducted for monometallic Pd, Pt, and 2:1 Pd-Pt catalysts. Monometallic palladium is fully oxidized in the full temperature range, whereas platinum addition promotes palladium reduction, even in a reactive oxidizing environment. The Pd/PdO weight ratio in bimetallic Pd-Pt 2:1 catalysts decreases from 98/2 to 10/90 in the 200-500 °C temperature range under the reaction conditions. Thus, platinum promotes the formation of the reduced palladium phase with a significantly lower activity than that of oxidized palladium. The study sheds light on the effect of platinum on the state of the active palladium surface under low-temperature dry lean methane combustion conditions, which is important for methane-emission control devices.

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Section: Resultssupporting

confidence: 81%

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al₂O₃: An In Situ X‐ray Absorption Study

Nassiri

Lee

et al. 2016

ChemPhysChem

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“…[3]When Pt nanoparticles were deposited on a planar model SiO 2 supportas a separate phase, heating for only 2 minutes at 650 °C in air caused the formation of bimetallic PtPd particles. [7] This previous work demonstrates that Pt species are mobile andcan be effectively trapped by PdO at high temperatures in air, forming bimetallic PtPd particleswhich are thermodynamically more stable. [7] The migration and vapor phase transport of precious metals in automotive exhaust catalysts has been documented in the literature.…”

Section: Introductionmentioning

confidence: 97%

Trapping mobile Pt species by PdO in diesel oxidation catalysts: Smaller is better

Xiong

Peterson

et al. 2016

Catalysis Today

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Pt is an active catalyst for treatment of diesel exhaust emissions but is known to sinter and form large particles under oxidizing conditions. Pd is added to suppress the sintering of Pt and improve the performance of the Pt catalysts through the formation of a Pt-Pd alloy. In a previous study, using model catalysts, we demonstrated that mobile Pt species can diffuse on the surface and get trapped on PdO particles, leading to the formation of metallic Pt-Pd alloys in flowing air at 650 °C. In this work we explore the implications of this trapping phenomenon to powder catalysts. We physically mixed Pt/MgAl 2 O 4 and PdO/La-Al 2 O 3 catalyst powders and aged them at 800 °C in air. Mobile Pt species emitted from the Pt/MgAl 2 O 4 migrated through the vapor phase and were trapped by PdO nanoparticles located on the La-Al 2 O 3 support. Since the Pt moved from the MgAl 2 O 4 support to the PdO, we infer that PdO is better at trapping Pt than the MgAl 2 O 4 support. We also investigated the effect of PdO particle size on the trapping efficiency for Pt. It was found that small PdO particles were more effective, leading to smaller size of Pt-Pd particles as confirmed by electron microscopy, x-ray diffraction and reactivity for methane oxidation.

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“…Previous studies have shown that Pt is very mobile at high temperatures in oxidising environments and can be effectively trapped by PdO nanoparticles ,. The studies demonstrated that upon heat treatment of specimens with initially separated Pt and PdO nanoparticles, the highly mobile Pt is trapped by the more stable PdO nanoparticles and alloyed Pt–Pd nanoparticles are formed, which are thermodynamically more stable and slow down further sintering by Ostwald ripening as well as the emission of Pt into the vapour phase .…”

Section: Resultsmentioning

confidence: 97%

Three‐Dimensional Probing of Catalyst Ageing on Different Length Scales: A Case Study of Changes in Microstructure and Activity for CO Oxidation of a Pt–Pd/Al₂O₃ Catalyst

et al. 2017

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The effects of thermal treatment on the microstructure of a Pt–Pd/Al2O3 oxidation catalyst and its activity for CO oxidation have been studied. The microstructural analysis was performed by using several high‐resolution electron microscopy techniques such as STEM, FIB/SEM slice & view, SEM and EDX. A combination of these analytic techniques and advanced TEM specimen preparation allowed for three‐dimensional probing at different length scales, avoiding the random character of conventionally crushed powder specimens owing to site specificity. A core–shell distribution of Pt–Pd nanoparticles within the alumina support particles, with enlarged nanoparticles (≈1.5 to 40 nm) present in the shell and small nanoparticles (<1.5 nm) in the core, was revealed in the untreated catalyst. A more uniform spatial distribution developed during thermal treatment at 700 °C or higher with larger nanoparticles forming in the core. Accompanying measurements of the catalytic activity for CO oxidation showed the detrimental effect of sintering of the small nanoparticles on the reaction rate and apparent activation energy of the reaction.

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Trapping of Mobile Pt Species by PdO Nanoparticles under Oxidizing Conditions

Cited by 82 publications

References 12 publications

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al₂O₃: An In Situ X‐ray Absorption Study

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al₂O₃: An In Situ X‐ray Absorption Study

Trapping mobile Pt species by PdO in diesel oxidation catalysts: Smaller is better

Three‐Dimensional Probing of Catalyst Ageing on Different Length Scales: A Case Study of Changes in Microstructure and Activity for CO Oxidation of a Pt–Pd/Al₂O₃ Catalyst

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Trapping of Mobile Pt Species by PdO Nanoparticles under Oxidizing Conditions

Cited by 82 publications

References 12 publications

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al2O3: An In Situ X‐ray Absorption Study

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al2O3: An In Situ X‐ray Absorption Study

Trapping mobile Pt species by PdO in diesel oxidation catalysts: Smaller is better

Three‐Dimensional Probing of Catalyst Ageing on Different Length Scales: A Case Study of Changes in Microstructure and Activity for CO Oxidation of a Pt–Pd/Al2O3 Catalyst

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Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al₂O₃: An In Situ X‐ray Absorption Study

Platinum Inhibits Low‐Temperature Dry Lean Methane Combustion through Palladium Reduction in Pd−Pt/Al₂O₃: An In Situ X‐ray Absorption Study

Three‐Dimensional Probing of Catalyst Ageing on Different Length Scales: A Case Study of Changes in Microstructure and Activity for CO Oxidation of a Pt–Pd/Al₂O₃ Catalyst