Self-Energy Spectroscopy and Artificial Neural Network

Youhei Yamaji

doi:10.7566/jpsj.94.031005

論文 Self-Energy Spectroscopy and Artificial Neural Network

Youhei Yamaji

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Youhei Yamaji. Self-Energy Spectroscopy and Artificial Neural Network. Journal of the Physical Society of Japan. 2025, 94 (3), . https://doi.org/10.7566/jpsj.94.031005

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(abstract)

The analysis of spectroscopy data has played an important role in untangling the complex dynamics of many-body electrons in quantum materials and making their emergent properties understandable. Spectroscopy measurements provide us with the responses of the many-body electrons in materials when energy and momentum are injected. These responses have been analyzed using a single-particle picture augmented by self-energy, which quantifies the deviation from simple free fermion excitation. While the self-energy is not directly observed in spectroscopy, it has been extracted from the obtained spectra by solving inverse problems. Especially, for superconductors, the analysis of self-energy is a key to understanding the origin of the superconductivity. The recent rise of machine learning has served to update the self-energy analysis of spectroscopy data and opened a new avenue for understanding the entangled nature of manybody electrons. In this article, self-energy analysis using the flexibility of neural networks is reviewed and positioned in the research trajectory from Bardeen–Cooper–Schrieffer superconductors to copper-oxide high-temperature superconductors.

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