In situ EXAFS characterization of nanoparticulate catalysts
In situ EXAFS characterization of nanoparticulate catalysts
X-ray absorption fine structure (XAFS) spectroscopy probes the structure and electronic properties of metal centers. Because it can be applied to noncrystalline materials, it is a key technique for probing nanoparticulate materials, such as colloidal and heterogeneous metal catalysts. The high brilliance of modern synchrotron radiation x-ray sources facilitates in situ studies, which provide direct structure–function relationships with both spatial and time resolution; this is especially effective when applied in combination with complementary techniques such as x-ray diffraction, mass spectrometry, and optical or vibrational spectroscopies. Tracking the particle formation of platinum-group metal catalysts, their behavior under reaction conditions, and the distribution of sites within a catalyst bed shows that this approach is essential for understanding the chemistry of these nanoparticles. Rather than behave as monolithic entities, nanoparticulate catalysts undergo rapid structural transformations induced by the gas environment and reaction conditions, and their lifetimes as catalysts depend on the reversibility of these changes.
1038-1043
Evans, John
05890433-0155-49fe-a65d-38c90ea25c69
Puig-Molina, Anna
8add0d28-bfe5-4508-9683-56c32bf1871c
Tromp, Moniek
48c1ebbb-579c-42b6-83bb-7188c668b322
December 2007
Evans, John
05890433-0155-49fe-a65d-38c90ea25c69
Puig-Molina, Anna
8add0d28-bfe5-4508-9683-56c32bf1871c
Tromp, Moniek
48c1ebbb-579c-42b6-83bb-7188c668b322
Evans, John, Puig-Molina, Anna and Tromp, Moniek
(2007)
In situ EXAFS characterization of nanoparticulate catalysts.
MRS Bulletin, 32 (12), .
Abstract
X-ray absorption fine structure (XAFS) spectroscopy probes the structure and electronic properties of metal centers. Because it can be applied to noncrystalline materials, it is a key technique for probing nanoparticulate materials, such as colloidal and heterogeneous metal catalysts. The high brilliance of modern synchrotron radiation x-ray sources facilitates in situ studies, which provide direct structure–function relationships with both spatial and time resolution; this is especially effective when applied in combination with complementary techniques such as x-ray diffraction, mass spectrometry, and optical or vibrational spectroscopies. Tracking the particle formation of platinum-group metal catalysts, their behavior under reaction conditions, and the distribution of sites within a catalyst bed shows that this approach is essential for understanding the chemistry of these nanoparticles. Rather than behave as monolithic entities, nanoparticulate catalysts undergo rapid structural transformations induced by the gas environment and reaction conditions, and their lifetimes as catalysts depend on the reversibility of these changes.
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Published date: December 2007
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Local EPrints ID: 146129
URI: http://eprints.soton.ac.uk/id/eprint/146129
ISSN: 0883-7694
PURE UUID: 58d9a62c-4119-4ad6-be88-1698c07abe52
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Date deposited: 03 Jun 2010 09:05
Last modified: 29 Oct 2024 02:32
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Author:
Anna Puig-Molina
Author:
Moniek Tromp
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