Melting phenomena of self-organized magnetic structures investigated by variational autoencoder

H. G. Yoon; D. B. Lee; S. M. Park; J. W. Choi; H. Y. Kwon; C. Won

doi:10.1016/j.cpc.2024.109329

Melting phenomena of self-organized magnetic structures investigated by variational autoencoder

H. G. Yoon, D. B. Lee, S. M. Park, J. W. Choi, H. Y. Kwon, C. Won

Research output: Contribution to journal › Article › peer-review

Abstract

The phase transition phenomenon is an important research topic in various physical studies. However, it is difficult to define the order parameters in many complex systems involving self-organized structures. We propose a method to define order parameters using a variational autoencoder network. To demonstrate these capabilities, we trained a deep learning network with a dataset composed of spin configurations in a chiral magnetic system at various temperatures. It removes thermal fluctuations from the input data and leaves the remaining structural information with a spin magnitude. We define an order parameter with magnitude of output spins and compare the results with those of conventional analysis. The comparison indicates similar results. Using the order parameter, the thermal properties of the chiral magnetic system were investigated by varying the physical parameters and data size.

Original language	English
Article number	109329
Journal	Computer Physics Communications
Volume	305
DOIs	https://doi.org/10.1016/j.cpc.2024.109329
Publication status	Published - Dec 2024

Bibliographical note

Publisher Copyright:
© 2024

Keywords

Critical temperature
Deep learning
Magnetism
Order parameter
Phase transition
Spontaneous symmetry breaking

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10.1016/j.cpc.2024.109329

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title = "Melting phenomena of self-organized magnetic structures investigated by variational autoencoder",

abstract = "The phase transition phenomenon is an important research topic in various physical studies. However, it is difficult to define the order parameters in many complex systems involving self-organized structures. We propose a method to define order parameters using a variational autoencoder network. To demonstrate these capabilities, we trained a deep learning network with a dataset composed of spin configurations in a chiral magnetic system at various temperatures. It removes thermal fluctuations from the input data and leaves the remaining structural information with a spin magnitude. We define an order parameter with magnitude of output spins and compare the results with those of conventional analysis. The comparison indicates similar results. Using the order parameter, the thermal properties of the chiral magnetic system were investigated by varying the physical parameters and data size.",

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T1 - Melting phenomena of self-organized magnetic structures investigated by variational autoencoder

AU - Yoon, H. G.

AU - Lee, D. B.

AU - Park, S. M.

AU - Choi, J. W.

AU - Kwon, H. Y.

AU - Won, C.

PY - 2024/12

Y1 - 2024/12

N2 - The phase transition phenomenon is an important research topic in various physical studies. However, it is difficult to define the order parameters in many complex systems involving self-organized structures. We propose a method to define order parameters using a variational autoencoder network. To demonstrate these capabilities, we trained a deep learning network with a dataset composed of spin configurations in a chiral magnetic system at various temperatures. It removes thermal fluctuations from the input data and leaves the remaining structural information with a spin magnitude. We define an order parameter with magnitude of output spins and compare the results with those of conventional analysis. The comparison indicates similar results. Using the order parameter, the thermal properties of the chiral magnetic system were investigated by varying the physical parameters and data size.

AB - The phase transition phenomenon is an important research topic in various physical studies. However, it is difficult to define the order parameters in many complex systems involving self-organized structures. We propose a method to define order parameters using a variational autoencoder network. To demonstrate these capabilities, we trained a deep learning network with a dataset composed of spin configurations in a chiral magnetic system at various temperatures. It removes thermal fluctuations from the input data and leaves the remaining structural information with a spin magnitude. We define an order parameter with magnitude of output spins and compare the results with those of conventional analysis. The comparison indicates similar results. Using the order parameter, the thermal properties of the chiral magnetic system were investigated by varying the physical parameters and data size.

KW - Critical temperature

KW - Deep learning

KW - Magnetism

KW - Order parameter

KW - Phase transition

KW - Spontaneous symmetry breaking

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JO - Computer Physics Communications

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Melting phenomena of self-organized magnetic structures investigated by variational autoencoder

Abstract

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Keywords

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