Hydride formation and stability on a Pd–SiO2 thin-film model catalyst studied by TEM and SAED

Jenewein, Bernd; Penner, Simon; Gabasch, Harald; Klötzer, Bernhard; Wang, Di; Knop‐Gericke, Axel; Schlögl, Robert; Hayek, K.

doi:10.1016/j.jcat.2006.04.012

Cited by 18 publications

(3 citation statements)

References 37 publications

(35 reference statements)

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“…The absorbed hydrogen is strongly retained in the metal and is released at 320°C. This temperature is similar to the one reported by other authors [44]. The results also demonstrate that some transformations of the palladium occur as can be concluded from its decreasing capacity for hydrogen storage.…”

Section: Phenol Oxidation With Catalytic Membrane Reactors Prepared Bsupporting

confidence: 91%

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Heterogeneous catalytic oxidation of phenol by in situ generated hydrogen peroxide applying novel catalytic membrane reactors

Osegueda

Dafinov

Llorca

et al. 2015

Chemical Engineering Journal

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This work presents a novel method for oxidation of organic matter in water solutions based on catalytic membrane reactors. The oxidant, hydrogen peroxide, is generated directly in the bulk of the liquid investigated. Commercial symmetric alumina hollow fibers have been used as a starting material thereafter introducing the active phases. It has been proven that two different catalysts are necessary in order to complete the overall reaction, as well as to generate hydrogen peroxide and a heterogeneous Fenton process. Palladium has been used for the hydrogen peroxide generation and a second active phase, transitional metal oxides or homogeneous Fe2+, has been used for the hydroxyl radical generation. An additional method for specific Pd loading to the reaction zone based on sputtering technique has been developed. All prepared catalytic membrane reactors (CMRs) are capable of generating hydrogen peroxide in amounts comparable to CMRs reported in the literature. The catalytic membrane reactors prepared by Pd impregnation show very high activity and stability in phenol oxidation reaching 40% of the generated H2O2 usage in the oxidation reaction. Despite the very high activity of the catalytic membrane reactors obtained by Pd sputtering in H2O2 production they suffer very fast deactivation. Specific reactivation including a calcination step has been found to be appropriate for the recovery of their activity. Additional experiments give new insights for better understanding of Pd deactivation especially when the metal particles are of nanometer sizes. (C) 2014 Elsevier B.V. All rights reserved.Postprint (published version

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Section: Phenol Oxidation With Catalytic Membrane Reactors Prepared Bsupporting

confidence: 91%

“…air, inert gas, hydrogen in [44]. The metal particles have been observed by HRTEM and selected area electron diffraction (SAED).…”

Section: Phenol Oxidation With Catalytic Membrane Reactors Prepared Bmentioning

confidence: 99%

Heterogeneous catalytic oxidation of phenol by in situ generated hydrogen peroxide applying novel catalytic membrane reactors

Osegueda

Dafinov

Llorca

et al. 2015

Chemical Engineering Journal

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“…Measurements were carried out at 100 °C to avoid the effects of the hydride phases observed by H 2 TPR (Figure ). These phases are usually considered solid solutions of hydrogen, which can interfere with the chemisorption results during the absorption/adsorption of hydrogen . Assuming spherical particles, particle size was calculated as d (nm) = 112/[ D (%)], where D is dispersion. ,, Dispersion decreased and particle size increased on used catalyst samples as compared to fresh ones (Table ).…”

Section: Resultsmentioning

confidence: 99%

Hydrodechlorination of Light Organochlorinated Compounds and Their Mixtures over Pd/TiO₂-Washcoated Minimonoliths

González

Bartoszek

Martin

et al. 2009

Ind. Eng. Chem. Res.

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The gas-phase catalytic hydrodechlorination (CHD) of dichloromethane (DCM), tetrachloroethylene (TTCE), and chloroform (CF) and their mixtures was studied over Pd/TiO2-washcoated cordierite minimonoliths. Experiments were carried out in a flow reactor at 120−300 °C, 1 bar, and 0.45 g min/mL. Catalytic runs with the pure compounds at 200 °C led to 60−100% conversion following the sequence CF > TTCE > DCM. Catalyst deactivation and regeneration were also examined. Lower conversions (between 30% and 95%) and catalyst deactivation were observed when mixtures of organochlorinated compounds where fed as reactants. DCM was the most affected when binary and ternary mixtures were used. Catalyst samples were characterized before and after reaction by various temperature-programmed studies (H2 TPR, He TPD, NH3 TPD, and TPO), H2 chemisorption, and XPS measurements. Most characterization studies were carried out using an online coupled mass spectrometer, thus allowing the parallel detection of different fragments and species corresponding to several hydrocarbons and HCl. In some experiments, a fast GC−ToF−MS system was used. The catalytic activity of spent samples was partially recovered by heating them in flowing air and then in 5% H2/N2. However, the initial reaction rate decreased by 62% over samples used in three consecutive runs when ternary mixtures were fed. Carbonaceous deposits of different nature and changes in the oxidation state of Pd (Pd0 to Pd2+ and Pd4+) appear to play key roles in catalyst deactivation, whereas acidity was found to remain almost the same for fresh and used catalyst samples. Carbonaceous deposits were removed by heating at temperatures lower than 400 °C in flowing air.

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How to Control the Selectivity of Palladium‐based Catalysts in Hydrogenation Reactions: The Role of Subsurface Chemistry

et al. 2012

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Discussed are the recent experimental and theoretical results on palladium-based catalysts for selective hydrogenation of alkynes obtained by a number of collaborating groups in a joint multi-method and multi-material approach. The critical modification of catalytically active Pd surfaces by incorporation of foreign species X into the sub-surface of Pd metal was observed by in situ spectroscopy for X=H, C under hydrogenation conditions. Under certain conditions (low H2 partial pressure) alkyne fragmentation leads to formation of a PdC surface phase in the reactant gas feed. The insertion of C as a modifier species in the sub-surface increases considerably the selectivity of alkyne semi-hydrogenation over Pd-based catalysts through the decoupling of bulk hydrogen from the outmost active surface layer. DFT calculations confirm that PdC hinders the diffusion of hydridic hydrogen. Its formation is dependent on the chemical potential of carbon (reactant partial pressure) and is suppressed when the hydrogen/alkyne pressure ratio is high, which leads to rather unselective hydrogenation over in situ formed bulk PdH. The beneficial effect of the modifier species X on the selectivity, however, is also present in intermetallic compounds with X=Ga. As a great advantage, such PdxGay catalysts show extended stability under in situ conditions. Metallurgical, clean samples were used to determine the intrinsic catalytic properties of PdGa and Pd3Ga7. For high performance catalysts, supported nanostructured intermetallic compounds are more preferable and partial reduction of Ga2O3, upon heating of Pd/Ga2O3 in hydrogen, was shown to lead to formation of PdGa intermetallic compounds at moderate temperatures. In this way, Pd5Ga2 and Pd2Ga are accessible in the form of supported nanoparticles, in thin film models, and realistic powder samples, respectively

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Hydride formation and stability on a Pd–SiO2 thin-film model catalyst studied by TEM and SAED

Cited by 18 publications

References 37 publications

Heterogeneous catalytic oxidation of phenol by in situ generated hydrogen peroxide applying novel catalytic membrane reactors

Heterogeneous catalytic oxidation of phenol by in situ generated hydrogen peroxide applying novel catalytic membrane reactors

Hydrodechlorination of Light Organochlorinated Compounds and Their Mixtures over Pd/TiO₂-Washcoated Minimonoliths

How to Control the Selectivity of Palladium‐based Catalysts in Hydrogenation Reactions: The Role of Subsurface Chemistry

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Hydride formation and stability on a Pd–SiO2 thin-film model catalyst studied by TEM and SAED

Cited by 18 publications

References 37 publications

Heterogeneous catalytic oxidation of phenol by in situ generated hydrogen peroxide applying novel catalytic membrane reactors

Heterogeneous catalytic oxidation of phenol by in situ generated hydrogen peroxide applying novel catalytic membrane reactors

Hydrodechlorination of Light Organochlorinated Compounds and Their Mixtures over Pd/TiO2-Washcoated Minimonoliths

How to Control the Selectivity of Palladium‐based Catalysts in Hydrogenation Reactions: The Role of Subsurface Chemistry

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Hydrodechlorination of Light Organochlorinated Compounds and Their Mixtures over Pd/TiO₂-Washcoated Minimonoliths