Machine-learning-assisted insight into spin ice Dy2Ti2O7

Anjana M. Samarakoon; Kipton Barros; Ying Wai Li; Markus Eisenbach; Qiang Zhang; Feng Ye; V. Sharma; Z. L. Dun; Haidong Zhou; Santiago A. Grigera; Cristian D. Batista; D. Alan Tennant

doi:10.1038/s41467-020-14660-y

Machine-learning-assisted insight into spin ice Dy₂Ti₂O₇

Anjana M. Samarakoon, Kipton Barros, Ying Wai Li, Markus Eisenbach, Qiang Zhang, Feng Ye, V. Sharma, Z. L. Dun, Haidong Zhou, Santiago A. Grigera, Cristian D. Batista, D. Alan Tennant

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

Abstract

Complex behavior poses challenges in extracting models from experiment. An example is spin liquid formation in frustrated magnets like Dy₂Ti₂O₇. Understanding has been hindered by issues including disorder, glass formation, and interpretation of scattering data. Here, we use an automated capability to extract model Hamiltonians from data, and to identify different magnetic regimes. This involves training an autoencoder to learn a compressed representation of three-dimensional diffuse scattering, over a wide range of spin Hamiltonians. The autoencoder finds optimal matches according to scattering and heat capacity data and provides confidence intervals. Validation tests indicate that our optimal Hamiltonian accurately predicts temperature and field dependence of both magnetic structure and magnetization, as well as glass formation and irreversibility in Dy₂Ti₂O₇. The autoencoder can also categorize different magnetic behaviors and eliminate background noise and artifacts in raw data. Our methodology is readily applicable to other materials and types of scattering problems.

Original language	English
Article number	892
Number of pages	9
Journal	Nature Communications
Volume	11
DOIs	https://doi.org/10.1038/s41467-020-14660-y
Publication status	Published - 14 Feb 2020

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title = "Machine-learning-assisted insight into spin ice Dy2Ti2O7",

abstract = "Complex behavior poses challenges in extracting models from experiment. An example is spin liquid formation in frustrated magnets like Dy2Ti2O7. Understanding has been hindered by issues including disorder, glass formation, and interpretation of scattering data. Here, we use an automated capability to extract model Hamiltonians from data, and to identify different magnetic regimes. This involves training an autoencoder to learn a compressed representation of three-dimensional diffuse scattering, over a wide range of spin Hamiltonians. The autoencoder finds optimal matches according to scattering and heat capacity data and provides confidence intervals. Validation tests indicate that our optimal Hamiltonian accurately predicts temperature and field dependence of both magnetic structure and magnetization, as well as glass formation and irreversibility in Dy2Ti2O7. The autoencoder can also categorize different magnetic behaviors and eliminate background noise and artifacts in raw data. Our methodology is readily applicable to other materials and types of scattering problems.",

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AU - Samarakoon, Anjana M.

AU - Barros, Kipton

AU - Li, Ying Wai

AU - Eisenbach, Markus

AU - Zhang, Qiang

AU - Ye, Feng

AU - Sharma, V.

AU - Dun, Z. L.

AU - Zhou, Haidong

AU - Grigera, Santiago A.

AU - Batista, Cristian D.

AU - Tennant, D. Alan

PY - 2020/2/14

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AB - Complex behavior poses challenges in extracting models from experiment. An example is spin liquid formation in frustrated magnets like Dy2Ti2O7. Understanding has been hindered by issues including disorder, glass formation, and interpretation of scattering data. Here, we use an automated capability to extract model Hamiltonians from data, and to identify different magnetic regimes. This involves training an autoencoder to learn a compressed representation of three-dimensional diffuse scattering, over a wide range of spin Hamiltonians. The autoencoder finds optimal matches according to scattering and heat capacity data and provides confidence intervals. Validation tests indicate that our optimal Hamiltonian accurately predicts temperature and field dependence of both magnetic structure and magnetization, as well as glass formation and irreversibility in Dy2Ti2O7. The autoencoder can also categorize different magnetic behaviors and eliminate background noise and artifacts in raw data. Our methodology is readily applicable to other materials and types of scattering problems.

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Machine-learning-assisted insight into spin ice Dy₂Ti₂O₇

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