Magnetic microstructure machine learning analysis

We use a machine learning approach to identify the importance of microstructure characteristics in causing magnetization reversal in ideally structured large-grained Nd2Fe14B permanent magnets. The embedded Stoner-Wohlfarth method is used as a reduced order model for determining local switching fiel...

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Bibliographic Details
Published in:JPhys materials 2019-01, Vol.2 (1)
Main Authors: Exl, Lukas, Fischbacher, Johann, Kovacs, Alexander, Oezelt, Harald, Gusenbauer, Markus, Yokota, Kazuya, Shoji, Tetsuya, Hrkac, Gino, Schrefl, Thomas
Format: Article
Language:English
Subjects:
Coercivity
feature selection
Field strength
Grain orientation
Machine learning
Magnetization reversal
Microstructure
Misalignment
model order reduction
Permanent magnets
Reduced order models
Switching
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Summary:We use a machine learning approach to identify the importance of microstructure characteristics in causing magnetization reversal in ideally structured large-grained Nd2Fe14B permanent magnets. The embedded Stoner-Wohlfarth method is used as a reduced order model for determining local switching field maps which guide the data-driven learning procedure. The predictor model is a random forest classifier which we validate by comparing with full micromagnetic simulations in the case of small granular test structures. In the course of the machine learning microstructure analysis the most important features explaining magnetization reversal were found to be the misorientation and the position of the grain within the magnet. The lowest switching fields occur near the top and bottom edges of the magnet. While the dependence of the local switching field on the grain orientation is known from theory, the influence of the position of the grain on the local coercive field strength is less obvious. As a direct result of our findings of the machine learning analysis we show that edge hardening via Dy-diffusion leads to higher coercive fields.
ISSN:2515-7639
2515-7639
DOI:10.1088/2515-7639/aaf26d