English

Machine learning-based mass density model for hard magnetic 14:2:1 phases using chemical composition-based features

Materials Science 2022-12-28 v1

Abstract

The Fe14Nd2B-based permanent magnets are technologically sought-after for energy conversion due to their unparalleled high energy product (520 kJ/m3). For such 14:2:1 phases of different compositions, determining the magnetization from the measured magnetic moment is often bottlenecked by lack of mass density. We present a machine learning (ML) mass density model for 14:2:1 phases using chemical composition-based features (representing 33 elements) and optionally lattice parameter (LP) features. The datasets for training and testing contain 190 phases (177 compositionally different) with their literature reported densities and LP. With an ML model with merely compositional features, we achieved a low mean-absolute-error of 0.51% on an unseen test-dataset.

Keywords

Cite

@article{arxiv.2207.00456,
  title  = {Machine learning-based mass density model for hard magnetic 14:2:1 phases using chemical composition-based features},
  author = {Anoop Kini and Amit Kumar Choudhary and Dominic Hohs and Andreas Jansche and Hermann Baumgartl and Ricardo Buettner and Timo Bernthaler and Dagmar Goll and Gerhard Schneider},
  journal= {arXiv preprint arXiv:2207.00456},
  year   = {2022}
}

Comments

16 pages, 4 figures

R2 v1 2026-06-24T12:11:14.408Z