The metal–support interaction in Pt/Y zeolite: evidence for a shift in energy of metal d-valence orbitals by Pt–H shape resonance and atomic XAFS spectroscopy

Koningsberger, D.C.; Graaf, Joost de; Mojet, Barbara; Ramaker, David E.; Miller, J.T.

doi:10.1016/s0926-860x(99)00320-8

Cited by 108 publications

(79 citation statements)

References 52 publications

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“…[13]. The present measurement data supports that Pt has metallic characteristics, which is agreed well with published results by Koningsberger et al [19,20].…”

Section: En-situ Exafs Measurement For 5 Wt% Pt Loading On Zeolite Casupporting

confidence: 93%

En-situ EXAFS investigation of zeolite supported Pt electrocatalyst structure

Yao

2017

Materials Technology

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Experimental investigation was carried out for Pt electrochemical performance and Pt particle size using 1.5 wt% and 5 wt% Pt loading on zeolite electrocatalysts made by Pt(NH 3 ) 4 (NO 3 ) 2 or Pt(NH 3 ) 4 (NO 3 ) 2 /NH 4 NO 3 salt with ion exchanged method and calcined at 350 o C and reduced at 400 o C or direct reduced at 400 o C, respectively. Cycle voltammetry measurement indicated that the hydrogen energy binding level on Pt surfaces is higher for electrocatalyst under direct reduction process than those made by calcination and reduction process. Extended X-ray adsorption fine structure measurement also revealed that Pt size for electrocatalyst made by calcination and reduction method is smaller than those made by direct reduced method. Furthermore, Pt size for electrocatalysts with 1.5wt% Pt loading on zeolite is smaller compared to those with 5 wt% Pt loading electrocatalysts.Aforementioned electrochemical performance of Pt zeolite electrocatalysts has depicted by a hypothesis of hydrogen spillover and surface conductance pathway.

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“…[13]. The present measurement data supports that Pt has metallic characteristics, which is agreed well with published results by Koningsberger et al [19,20].…”

Section: En-situ Exafs Measurement For 5 Wt% Pt Loading On Zeolite Casupporting

confidence: 93%

En-situ EXAFS investigation of zeolite supported Pt electrocatalyst structure

Yao

2017

Materials Technology

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“…Two possible pathways either the surface mobility of adsorbed species or hydrogen adatoms/H + ion may spill over through zeolite framework or on electrode surface [13] in which hydrogen ions (H + ) were able to form OH group with carbon/zeolite acidic surface oxides. The hydrogen spillover on Pt and zeolite acidic sites has also been studied in gas phase [18], in which an anti-bonding state of Pt-H interaction relating to the electronic properties of the catalytic active sites has been observed [4]. This finding can also be used to explain the hydrogen spillover between Pt electrode and solution in electrochemical environment.…”

Section: The Cyclic Voltammetry (Cv) Measurementmentioning

confidence: 96%

“…Nevertheless, the surface oxygen groups, which form the anchoring sites of metallic precursors and metals, are well-known in determining the catalyst supporting material properties [3]. Koningsberger et al [4] has investigated the influence of oxygen atom charge transfer on zeolite using the extended X-Ray adsorption Fine Structure (EXAFS). The increasing of electronegativity nearby the support oxygen atoms was found to increase zeolite alkalinity.…”

Section: Introductionmentioning

confidence: 99%

Proton Modified Pt Zeolite Fuel Cell Electrocatalysts

Yao

Mirzaii³

2015

Renewable Energy in the Service of Mankind Vol I

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NaY Zeolite has been selected as a suitable material to host 1.5 wt% Platinum (Pt) loading on zeolite using ion exchange methods of Pt(NH 3 ) 4 (NO 3 ) 2 without excess NH 4 NO 3 nitrate and Pt(NH 3 ) 4 (NO 3 ) 2 with excess NH 4 NO 3 nitrate. The structure/reactivity relationship of Pt nanoparticle was experimentally studied via Nafion @ bound electrodes to investigate the interaction nature of Pt with zeolite and electron transfer. By using extended X-ray adsorption fine structure technique, Pt particle size was predicted as 0.7 -1.5 nm. It was found Pt oxides can be electrochemically reduced via a hydrogen 'spillover' phenomenon. A highly dispersed small Pt particle distribution can be achieved with excessive H + ions on zeolite acidic sites.

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“…Tauster et al (1978 introduced the concept of strong metal support interaction (SMSI) and observed that some of the metal particles from Group VIII supported on TiO 2 and other reducible oxides lose their chemisorptive properties towards H 2 and CO, when they are reduced at temperature higher than 773 K. Besides, it has been shown that the electron transfer from the oxygen atom present on the support to the metal particle can enhance the electron density and hence the catalytic activity (Triantafillou et al 1995, Watwe et al 1998. In addition, a model based on a study made by extended X-ray absorption spectroscopy (EXAFS), X-ray photoelectron spectroscopy (XPS) and fourier transform infra-red spectroscopy (FTIR) has shown that due to metal-support interaction, a change in the energy position of the metal valence orbital takes place, a factor which affect the catalytic activity (Koningsberger et al 2000. Besides, the charge transfer process between the metal particles and the support can cause significant modification in their catalytic properties.…”

Section: Introductionmentioning

confidence: 99%

Activity and Stability of Dispersed Multi Metallic Pt-based Catalysts for CO Tolerance in Proton Exchange Membrane Fuel Cell Anodes

Hassan¹,

Ticianelli²

2018

An. Acad. Bras. Ciênc.

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Studies aiming at improving the activity and stability of dispersed W and Mo containing Pt catalysts for the CO tolerance in proton exchange membrane fuel cell (PEMFC) anodes are revised for the following catalyst systems: (1) a carbon supported PtMo electrocatalyst submitted to heat treatments; (2) Pt and PtMo nanoparticles deposited on carbon-supported molybdenum carbides (Mo2C/C); (3) ternary and quaternary materials formed by PtMoFe/C, PtMoRu/C and PtMoRuFe/C and; (4) Pt nanoparticles supported on tungsten carbide/carbon catalysts and its parallel evaluation with carbon supported PtW catalyst. The heat-treated (600 oC) Pt-Mo/C catalyst showed higher hydrogen oxidation activity in the absence and in the presence of CO and better stability, compared to all other Mo-containing catalysts. PtMoRuFe, PtMoFe, PtMoRu supported on carbon and Pt supported on Mo2C/C exhibited similar CO tolerances but better stability, as compared to as-prepared PtMo supported on carbon. Among the tungsten-based catalysts, tungsten carbide supported Pt catalyst showed reasonable performance and reliable stability in comparison to simple carbon supported PtW catalyst, though an uneven level of catalytic activity towards H2 oxidation in presence of CO is observed for the former as compared to Mo containing catalyst. However, a small dissolution of Mo, Ru, Fe and W from the anodes and their migration toward cathodes during the cell operation is observed. These results indicate that the fuel cell performance and stability has been improved but not yet totally resolved.

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The metal–support interaction in Pt/Y zeolite: evidence for a shift in energy of metal d-valence orbitals by Pt–H shape resonance and atomic XAFS spectroscopy

Cited by 108 publications

References 52 publications

En-situ EXAFS investigation of zeolite supported Pt electrocatalyst structure

En-situ EXAFS investigation of zeolite supported Pt electrocatalyst structure

Proton Modified Pt Zeolite Fuel Cell Electrocatalysts

Activity and Stability of Dispersed Multi Metallic Pt-based Catalysts for CO Tolerance in Proton Exchange Membrane Fuel Cell Anodes

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