Abstract
Methane oxidation over Pd–Pt/Al2O3 model catalysts calcined at three different conditions is investigated using operando diffuse reflectance infrared Fourier transform spectroscopy and mass spectrometry, and in situ X-ray absorption spectroscopy while cycling the feed gas stoichiometry between lean (net-oxidising) and rich (net-reducing) conditions. When calcined in air, alloy Pd–Pt nanoparticles are present only on catalysts subjected to elevated temperature (800 ◦C) whereas calcination at lower temperature (500◦C) leads to segregated Pt and Pd nanoparticles on the support. Here, we show that the alloy Pd–Pt nanoparticles undergo reversible changes in surface structure and composition during transient methane oxidation exposing a PdO surface during lean conditions and a metallic Pd–Pt surface (Pd enriched) under rich conditions. Alloyed particles seem more active for methane oxidation than their monometallic counterparts and, furthermore, an increased activity for methane oxidation is clearly observed under lean conditions when PdO has developed on the surface, analogous to monometallic Pd catalysts. Upon introducing rich conditions, partial oxidation of methane dominates over total oxidation forming adsorbed carbonyls on the noble metal particles. The carbonyl spectra for the three samples show clear differences originating from different surfaces exposed by alloyed vs. non-alloyed particles. The kinetics of the noble metal oxidation and reduction processes as well as carbonyl formation during transient methane oxidation are discussed.
Highlights
Hydrocarbon emissions from natural gas engines consist mostly of unburned methane
This work presents a study of transient effects in the methane oxidation reaction over a series of bimetallic Pd–Pt catalysts supported on alumina and calcined at different temperatures and conditions
A good understanding of how the catalytic activity for methane oxidation and formed surface species depend on the feed stoichiometry and chemical state and structure of the Pd–Pt nanoparticles is demonstrated using operando DRIFTS and in situ X-ray absorption spectroscopy (XAS) techniques
Summary
Hydrocarbon emissions from natural gas engines consist mostly of unburned methane. As methane is a strong greenhouse gas, it is of vital importance to remove it from the exhausts. Since our previous results on the oxidation behavior of Pd–Pt catalysts reveal oxidation of Pt for the F500 sample, a similar experiment has been performed by measuring the Pt LIII edge during methane oxidation.
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