Predicting ELNES/XANES spectra by machine learning with an atomic coordinate-independent descriptor and its application to ground-state electronic structures

IF 2.5 3区工程技术 Q1 MICROSCOPY

Micron Pub Date : 2024-09-19 DOI:10.1016/j.micron.2024.103723

Po-Yen Chen , Kiyou Shibata , Katsumi Hagita , Tomohiro Miyata , Teruyasu Mizoguchi

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引用次数: 0

Abstract

ELNES/XANES spectra can be observed using TEM or synchrotron radiation and can elucidate the unoccupied state electronic structures of an excited states. The computation of their features is usually demanding substantial computational resources due to the requisite structure optimization and electronic structure calculations. Herein, we leverage a machine learning technique alongside an atomic-coordinate-independent descriptor, SMILES, to yield the ELNES/XANES spectra, directly, with heightened precision. Moreover, our approach extends to obtain ground state electronic structure, namely PDOS at both occupied and unoccupied ground states, underscoring its viability for a ground-state spectroscopy. Our study revealed that incorporation of long-SMILES molecules into the training dataset enhances prediction accuracy for such molecular structures. This study's direct derivation of spectroscopy from SMILES strings holds promise for expediting spectroscopic inquiries.

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利用与原子坐标无关的描述符通过机器学习预测 ELNES/XANES 光谱及其在基态电子结构中的应用。

ELNES/XANES 光谱可通过 TEM 或同步辐射观测到，并能阐明激发态的非占位电子结构。由于需要进行结构优化和电子结构计算，因此计算其特征通常需要大量的计算资源。在这里，我们利用机器学习技术和与原子序数无关的描述符 SMILES，直接获得了精确度更高的 ELNES/XANES 光谱。此外，我们的方法还扩展到了基态电子结构的获取，即有基态和无基态的 PDOS，突出了其在基态光谱学中的可行性。我们的研究表明，将长 SMILES 分子纳入训练数据集可提高此类分子结构的预测准确性。这项研究从 SMILES 字符串直接推导出光谱，为加快光谱查询带来了希望。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Micron 工程技术-显微镜技术

CiteScore

4.30

自引率

4.20%

发文量

100

审稿时长

31 days

期刊介绍： Micron is an interdisciplinary forum for all work that involves new applications of microscopy or where advanced microscopy plays a central role. The journal will publish on the design, methods, application, practice or theory of microscopy and microanalysis, including reports on optical, electron-beam, X-ray microtomography, and scanning-probe systems. It also aims at the regular publication of review papers, short communications, as well as thematic issues on contemporary developments in microscopy and microanalysis. The journal embraces original research in which microscopy has contributed significantly to knowledge in biology, life science, nanoscience and nanotechnology, materials science and engineering.