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Robust retrieval of material chemical states in X-ray microspectroscopy

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arxiv 2308.04207 v1 pith:VU2MAFVS submitted 2023-08-08 cs.CV

Robust retrieval of material chemical states in X-ray microspectroscopy

classification cs.CV
keywords chemicalframeworkstatesx-rayalternativeanalysisdatamaterial
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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X-ray microspectroscopic techniques are essential for studying morphological and chemical changes in materials, providing high-resolution structural and spectroscopic information. However, its practical data analysis for reliably retrieving the chemical states remains a major obstacle to accelerating the fundamental understanding of materials in many research fields. In this work, we propose a novel data formulation model for X-ray microspectroscopy and develop a dedicated unmixing framework to solve this problem, which is robust to noise and spectral variability. Moreover, this framework is not limited to the analysis of two-state material chemistry, making it an effective alternative to conventional and widely-used methods. In addition, an alternative directional multiplier method with provable convergence is applied to obtain the solution efficiently. Our framework can accurately identify and characterize chemical states in complex and heterogeneous samples, even under challenging conditions such as low signal-to-noise ratios and overlapping spectral features. Extensive experimental results on simulated and real datasets demonstrate its effectiveness and reliability.

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