Abstract
X-ray absorption near-edge structure (XANES) spectra are the fingerprint of the local atomic and electronic structures around the absorbing atom. However, the quantitative analysis of these spectra is not straightforward. Even with the most recent advances in this area, for a given spectrum, it is not clear a priori which structural parameters can be refined and how uncertainties should be estimated. Here, we present an alternative concept for the analysis of XANES spectra, which is based on machine learning algorithms and establishes the relationship between intuitive descriptors of spectra, such as edge position, intensities, positions, and curvatures of minima and maxima on the one hand, and those related to the local atomic and electronic structure which are the coordination numbers, bond distances and angles and oxidation state on the other hand. This approach overcoms the problem of the systematic difference between theoretical and experimental spectra. Furthermore, the numerical relations can be expressed in analytical formulas providing a simple and fast tool to extract structural parameters based on the spectral shape. The methodology was successfully applied to experimental data for the multicomponent Fe:SiO2 system and reference iron compounds, demonstrating the high prediction quality for both the theoretical validation sets and experimental data.
Highlights
X-ray absorption spectroscopy is widely employed to probe the local atomic and electronic structure around the absorbing atom[1,2,3]
The pre-edge shape depends on the number of electrons in the d-shell[4], its intensity is proportional to the amount of 3d–4p hybridization[5], while its energy position can be employed to realize the calibration of the 3d metal oxidation state[6]
K-edge X-ray absorption near-edge structure (XANES) of metals with an fcc structure is further characterized by the splitting of the main peak into M1 and M2 features
Summary
X-ray absorption spectroscopy is widely employed to probe the local atomic and electronic structure around the absorbing atom[1,2,3]. The pre-edge shape depends on the number of electrons in the d-shell[4], its intensity is proportional to the amount of 3d–4p hybridization[5], while its energy position can be employed to realize the calibration of the 3d metal oxidation state[6]. K-edge XANES of metals with an fcc structure is further characterized by the splitting of the main peak into M1 and M2 features. Characteristic spectral features can be further established for the K-edges of light atoms, L2,3 edges for 3d metals with strong multiplet splitting, or L2,3 spectra for 4d metals possessing a characteristic white line. The above-mentioned spectral features are recognized as descriptors, and the relationships between spectral descriptors and the structural ones (coordination number, geometry, bond distances, angles...) can be established, for example, by using machine learning (ML) algorithms.
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