Your search keyword '"Sawada, Ryohto"' showing total 3 results

1. High-throughput investigation of stability and Li diffusion of doped solid electrolytes via neural network potential without configurational knowledge.

Author

Sawada, Ryohto, Nakago, Kosuke, Shinagawa, Chikashi, and Takamoto, So

Subjects

*SOLID electrolytes, *KIRKENDALL effect, *SUPERIONIC conductors, *STRUCTURAL optimization, *ACTIVATION energy, *MOLECULAR dynamics, *SOLID state batteries

Abstract

Solid electrolytes hold substantial promise as vital components of all-solid-state batteries. Enhancing their performance necessitates simultaneous improvements in their stability and lithium conductivity. These properties can be calculated using first-principles simulations, provided that the crystal structure of the material and the diffusion pathway through the material are known. However, solid electrolytes typically incorporate dopants to enhance their properties, necessitating the optimization of the dopant configuration for the simulations. Yet, performing such calculations via the first-principles approach is so costly that existing approaches usually rely on predetermined dopant configurations informed by existing knowledge or are limited to systems doped with only a few atoms. The proposed method enables the optimization of the dopant configuration with the support of neural network potential (NNP). Our approach entails the use of molecular dynamics to analyze the diffusion after the optimization of the dopant configuration. The application of our approach to Li 10 MP 2 S 12 - x O x (M = Ge, Si, or Sn) reproduce the experimental results well. Furthermore, analysis of the lithium diffusion pathways suggests that the activation energy of diffusion undergoes a percolation transition. This study demonstrates the effectiveness of NNPs in the systematic exploration of solid electrolytes. [ABSTRACT FROM AUTHOR]

Published

2024

2. Model-Free Cluster Analysis of Physical Property Data using Information Maximizing Self-Argument Training.

Author

Sawada, Ryohto, Iwasaki, Yuma, and Ishida, Masahiko

Subjects

*ARTIFICIAL intelligence, *NEURAL circuitry, *HYSTERESIS, *X-ray diffraction, *CLUSTER analysis (Statistics)

Abstract

We present semi-supervised information maximizing self-argument training (IMSAT), a neural network-based classification method that works without the preparation of labeled data. Semi-supervised IMSAT can amplify specific differences and avoid undesirable misclassification in accordance with the purpose. We demonstrate that semi-supervised IMSAT has a comparable performance with existing methods for semi-supervised learning of image classification and can also classify real experimental data (X-ray diffraction patterns and thermoelectric hysteresis curves) in the same way even though their shape and dimensions are different. Our algorithm will contribute to the automation of big data processing and artificial intelligence-driven material development. [ABSTRACT FROM AUTHOR]

Published

2020

3. Machine-learning guided discovery of a new thermoelectric material.

Author

Iwasaki, Yuma, Takeuchi, Ichiro, Stanev, Valentin, Kusne, Aaron Gilad, Ishida, Masahiko, Kirihara, Akihiro, Ihara, Kazuki, Sawada, Ryohto, Terashima, Koichi, Someya, Hiroko, Uchida, Ken-ichi, Saitoh, Eiji, and Yorozu, Shinichi

Abstract

Thermoelectric technologies are becoming indispensable in the quest for a sustainable future. Recently, an emerging phenomenon, the spin-driven thermoelectric effect (STE), has garnered much attention as a promising path towards low cost and versatile thermoelectric technology with easily scalable manufacturing. However, progress in development of STE devices is hindered by the lack of understanding of the fundamental physics and materials properties responsible for the effect. In such nascent scientific field, data-driven approaches relying on statistics and machine learning, instead of more traditional modeling methods, can exhibit their full potential. Here, we use machine learning modeling to establish the key physical parameters controlling STE. Guided by the models, we have carried out actual material synthesis which led to the identification of a novel STE material with a thermopower an order of magnitude larger than that of the current generation of STE devices. [ABSTRACT FROM AUTHOR]

Published

2019