4.7 Article

Laboratory-scale in situ X-ray absorption spectroscopy of a palladium catalyst on a compact inverse-Compton scattering X-ray beamline

期刊

JOURNAL OF ANALYTICAL ATOMIC SPECTROMETRY
卷 36, 期 12, 页码 2649-2659

出版社

ROYAL SOC CHEMISTRY
DOI: 10.1039/d1ja00274k

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资金

  1. Center for Advanced Laser Applications (CALA)
  2. German Research Foundation (DFG)
  3. Technical University of Munich (TUM)
  4. Chinese Scholarship Council (CSC)

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X-ray absorption spectroscopy is a crucial technique for catalyst characterization and is typically carried out at synchrotron facilities. This study demonstrates in situ experiments conducted on a palladium-based catalyst at a compact synchrotron facility, showcasing improved catalytic decarboxylation activity.
X-ray absorption spectroscopy (XAS) is one of the most important techniques used for catalyst characterization, and is often conducted under in situ conditions. Such experiments are typically carried out at synchrotrons, despite the significant improvements in laboratory-based XAS systems in recent years. The limited spectral flux density of X-ray tubes restricts these setups to ex situ or in situ experiments conducted over a large time scale, especially for X-ray energies above 15 keV. In this paper, we present an in situ experiment performed on a palladium-based catalyst at the Munich Compact Light Source (MuCLS), a compact synchrotron facility based on inverse Compton X-ray scattering (ICS). Its brilliant, low-divergence, energy-tuneable X-ray beam makes such a compact facility well suited for XAS techniques, especially with in situ experiments. In this study, we investigated a hydrogen-pretreated Pd/C catalyst, which significantly improves the catalytic decarboxylation activity compared to a bare Pd(0)/C catalyst. We measured a series of X-ray absorption near-edge structures (XANES) at the Pd K-edge (24.4 keV), with a time resolution of <5 min per spectrum. The spectral quality achieved is comparable to spectra obtained from synchrotron measurements. The results infer that the formation of alpha-phase palladium hydride may be the reason for the enhanced performance of the hydrogen-pretreated Pd/C catalyst.

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