AI Article Synopsis
- Simulations of excited state properties like spectral functions are computationally intensive, limiting high-throughput modeling.
- A proof of concept shows that graph-based neural networks can accurately predict x-ray absorption near-edge structure spectra for molecules, capturing key peaks.
- This method not only aids in spectral analysis but can also be integrated with structure search algorithms for efficient exploration of material configurations, enhancing material design and discovery.
Article Abstract
Simulations of excited state properties, such as spectral functions, are often computationally expensive and therefore not suitable for high-throughput modeling. As a proof of principle, we demonstrate that graph-based neural networks can be used to predict the x-ray absorption near-edge structure spectra of molecules to quantitative accuracy. Specifically, the predicted spectra reproduce nearly all prominent peaks, with 90% of the predicted peak locations within 1 eV of the ground truth. Besides its own utility in spectral analysis and structure inference, our method can be combined with structure search algorithms to enable high-throughput spectrum sampling of the vast material configuration space, which opens up new pathways to material design and discovery.
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| http://dx.doi.org/10.1103/PhysRevLett.124.156401 | DOI Listing |
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