# Enabling the production of large HRE lean magnets with homogeneous microstructure - the particle size effect in the 2-powder method and core-shell development in large magnets

https://mdr.nims.go.jp/datasets/604bc717-9c0c-4921-8953-2091653de387

## File

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## Id

604bc717-9c0c-4921-8953-2091653de387

## Local identifier



## Visibility

open_to_public

## State

published

## Created at

2025-09-02T00:21:50.148053Z

## Updated at

2025-09-11T07:31:55.804601Z

## Published at

2025-09-11T07:20:08.003736Z

## Doi

https://doi.org/10.48505/nims.5693

## First published url



## Date published



## Recorded date published



## Resource type

conference_presentation

## Manuscript type

na

## Collection

- id: d28f086a-61aa-4bc7-bcae-5a1078cbc6c7
  identifier: https://mdr.nims.go.jp/pid/d28f086a-61aa-4bc7-bcae-5a1078cbc6c7
  title: The 28th International Workshop on Rare Earth and Future Permanent Magnets
    and Their Applications (REPM2025)

## Title

- title: Enabling the production of large HRE lean magnets with homogeneous microstructure
    - the particle size effect in the 2-powder method and core-shell development in
    large magnets
  title_type: original
  lang: en

## Description

- description: "Climate change and the expansion of renewable energies make green
    technologies like emobility and wind energy increasingly important. For the most
    efficient use, Nd-Fe-Bbased magnets are the material of choice in generators of
    wind turbines and traction motors of electric vehicles. Because of operation temperatures
    up to 180 °C the use of heavy rare earths (HREs) like Dy or Tb is necessary to
    increase the temperature stability. Geopolitical reasons and the high price of
    HREs make them very critical. Therefore, the grain boundary diffusion process
    (GBDP) is industrially used as a resource-saving approach since it allows engineering
    a so-called core-shell microstructure within the magnets where the HREs are only
    located in the outer regions of the magnetic grains. As a result, the coercivity
    is increased without a significantly decreasing remanence.\r\n\r\nThe 2-powder
    method (2PM) is a promising approach to reducing the amount of HREs. In this method,
    two powders with different particle sizes are blended and sintered. The finer
    powder shows a higher magnetocrystalline anisotropy because of a higher HRE content.
    Like in the GBDP, a core-shell structure develops throughout the magnet. However,
    the advantages of the 2PM are the avoidance of cost-intensive and time-consuming
    coating and diffusion treatment processes and the production of magnets independent
    of their size.\r\n\r\nIn the first part of this study, different HRE-free main
    phase powders (MP) with D50 values of 3.7 μm and 5.4 μm, and finer HRE-containing
    anisotropy powders (AP) with D50 values of 2.5 μm, 3.1 μm, 3.6 μm, and 4.0 μm
    were produced via jet-milling. After blending and sintering, the magnetic properties
    were measured to investigate the particle size effect, and SEM investigations
    were performed to analyze the core-shell development. The different particle size
    ratios and resulting magnet properties are listed in Table 1. For the powder blends
    with the fine MP (MPf) the coercivity gain of the magnets after applying the 2PM
    is about 450 kA/m and for the powder blends with the large MP (MPl) it is about
    350 kA/m leading to the assumption that the difference of 100 kA/m is related
    to the particle size effect, meaning that smaller grain sizes of a magnet lead
    to fewer surface defects at which the magnetization reversal may initiate.\r\n\r\nThe
    core-shell structure was observed for all produced magnets, even if the different
    powders showed similar particle sizes. The observed shell thicknesses seemed not
    to be affected by the particle size ratio because the shell thicknesses for all
    magnets are in the same range of 2 – 3 μm and are, therefore, assumed to be only
    related to the presence of the APs in the powder blends before sintering. So,
    the mechanism for the core-shell development is considered to be the precipitation
    of the HREs during the sintering procedure.\r\n\r\nIn the second part of this
    study, a huge 340 g magnet with approx. 45 mm in height and 40 mm in diameter
    was produced with the 2PM to investigate this hypothesis of precipitation as the
    mechanism for core-shell development on the one hand and to demonstrate the possibility
    of engineering a core-shell structure in magnets independent of their size (Figure
    1). Smaller samples with 5 mm in height and 12 mm in diameter were cut out of
    the huge 340 g magnet for advanced microstructural characterization using SEM,
    MOKE, EBSD, TEM, and 3D atom probe tomography.\r\n\r\nFinally, a Life Cycle Assessment
    (LCA) was done to compare the global warming potential of conventional processing
    of sintered magnets, the GBDP, and the 2PM approach on the pilot plant for magnet
    manufacturing at Fraunhofer IWKS, Germany. This pilot plant includes all necessary
    production steps in an industrially relevant batch size starting with up to 50
    kg of strip casting, hydrogen decrepitation, jet-milling, alignment and compaction,
    sintering, cutting, and coating as well as physical vapor deposition for performing
    the GBDP."
  description_type: abstract
  lang: en

## Creator

- name: Konrad Opelt
  role: author
  organization: Fraunhofer IWKS, Fraunhofer Research Institution for Materials Recycling
    and Resource Strategies, Aschaffenburger Str. 121, 63457 Hanau, Germany
- name: Mario Schönfeldt
  role: author
  organization: Fraunhofer IWKS, Fraunhofer Research Institution for Materials Recycling
    and Resource Strategies, Aschaffenburger Str. 121, 63457 Hanau, Germany
- name: Chi-Chia Lin
  role: author
  organization: Fraunhofer IWKS, Fraunhofer Research Institution for Materials Recycling
    and Resource Strategies, Aschaffenburger Str. 121, 63457 Hanau, Germany
- name: Jürgen Gassmann
  role: author
  organization: Fraunhofer IWKS, Fraunhofer Research Institution for Materials Recycling
    and Resource Strategies, Aschaffenburger Str. 121, 63457 Hanau, Germany
- name: Imants Dirba
  role: author
  organization: TU Darmstadt, Department of Materials and Geosciences, Functional
    Materials, Peter-Grünberg-Str. 16, 64287 Darmstadt, Germany
- name: Abdullatif Durgun
  role: author
  organization: TU Darmstadt, Department of Materials and Geosciences, Functional
    Materials, Peter-Grünberg-Str. 16, 64287 Darmstadt, Germany
- name: Matic Jovičević-Klug
  role: author
  organization: Max-Planck- Institute for Sustainable Materials GmbH, Department of
    Microstructure Physics and Alloy Design, Max-Planck-Str. 1, 40237 Düsseldorf,
    Germany
- name: Oliver Gutfleisch
  role: author
  organization: TU Darmstadt, Department of Materials and Geosciences, Functional
    Materials, Peter-Grünberg-Str. 16, 64287 Darmstadt, Germany

## Contact agent



## Publisher

organization: National Institute for Materials Science (NIMS)

## Managing organization



## Keyword

- subject: REPM2025
  schema: not_defined
- subject: Nd-Fe-B
  schema: not_defined
- subject: life-cycle-assessment
  schema: not_defined
- subject: permanent magnets
  schema: not_defined
- subject: core-shell structure
  schema: not_defined
- subject: sustainable manufacturing
  schema: not_defined

## Rights

- identifier: https://creativecommons.org/licenses/by/4.0/

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## Data origin

- data_origin_type: other

## Embargo



## Journal



## Conference

name: REPM2025
start_date: 2025-07-27
end_date: 2025-07-31
identifier: https://www.nims.go.jp/mmu/repm2025/

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## Fileset

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  filename: REPM2025_O1-5_Opelt.pdf
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  size: 3856182
  md5: 97f4e51545460b0cabbe99609c0aa274
- id: f3bccdad-9628-41f7-a5b0-ba7674c804be
  filename: "(abstract) O1-5_Table1-Figure1.jpeg"
  content_type: image/jpeg
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## Thumbnail

fileset_id: 9e21d841-6c22-448c-9127-11618213b6df
filename: REPM2025_O1-5_Opelt.pdf