# In-Depth investigation of the sub-micronic equiaxed grain microstructure of a NdFeB permanent magnet fabricated by Laser Powder Bed Fusion

https://mdr.nims.go.jp/datasets/b5e0fea7-c584-44ee-9210-ba0dc196b90f

## File

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## Id

b5e0fea7-c584-44ee-9210-ba0dc196b90f

## Local identifier



## Visibility

open_to_public

## State

published

## Created at

2025-08-30T01:55:29.224493Z

## Updated at

2025-09-11T07:31:28.521170Z

## Published at

2025-09-11T07:20:16.260958Z

## Doi

https://doi.org/10.48505/nims.5687

## 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: In-Depth investigation of the sub-micronic equiaxed grain microstructure
    of a NdFeB permanent magnet fabricated by Laser Powder Bed Fusion
  title_type: original
  lang: en

## Description

- description: "Laser Powder Bed Fusion (LPBF) has been identified as an interesting
    technique for the manufacturing of high coercivity NdFeB magnets thanks to the
    emergence of submicronic microstructures [1]. However, most studies have focused
    on commercial MQP-S powder whose chemical composition is not optimized for the
    formation of a Nd-rich intergranular phase, thus resulting in poor magnetic properties
    [2]. In this work, magnets have been elaborated using a specific and unique powder
    fabricated with an in-house experimental pilot line allowing to adapt both the
    size (in the case of this study a narrowly-distributed powder with a volumic D50
    of 40 μm) and the chemical composition of the material as desired.\r\n\r\nThe
    microstructure of the magnets has been characterized down to the nano-scale using
    TEM analyses. It is composed of sub-micronic Nd2Fe14B grains ranging from 100-200
    nm to 1-2 μm and multiple Nd-rich phases at grain boundaries. Interestingly, there
    seems to be a NdOx phase (Fm3m structure) mainly present at the triple junctions
    (TJ) with a lattice parameter of circa 5.5 angstroms, while the fine grain boundaries
    are composed of metallic Nd with traces of Cu and Ga. As for sintered magnets,
    non-homogeneous grain boundaries have been identified in the as-built materials,
    which prevents high coercivity to be obtained. However, the magnetic properties
    can be improved by annealing heat treatments around 500-600°C that allow the grain
    boundary phase to reorganize. This effect is made possible thanks to the presence
    of addition elements (in particular Cu and Ga) which lower the melting temperature
    of the Nd-rich phase [3].\r\n\r\nMultiple precipitates have been observed inside
    of the grains sizing from 10 to 100 nm. They have been identified either as NdOx
    Fm3m but this time with a lattice parameter of circa 5.2 angstroms, either as
    Nd2O3 P63/mmc. These results agree with reference works on sintered magnets [4].\r\n\r\nIn
    this context, the origin of the formation of an almost fully equiaxed microstructure
    has been investigated. Indeed, in LPBF fabrications, the formation of columnar
    grains is generally preponderant, as the formation of equiaxed grains is not expected
    due to the strong thermal gradients generated during the process. Using both a
    numerical model to provide information on the cooling conditions of the alloy
    during LPBF [5] and experimental observations on crystallographic orientations
    between Nd oxide precipitates and Nd2Fe14B, it has been suggested that the oxides
    could act as nuclei for the formation of the Nd2Fe14B phase.\r\n\r\nSuch a result
    could be of strong interest for future optimization of the LPBF process for Nd2Fe14B
    magnets as Nd oxides are naturally present in the alloy due to fabrication conditions
    of the powder, and as sub-micronic grains are beneficial for the formation of
    high coercivity magnets.\r\n\r\nReferences:\r\n[1] O. Tosoni et al., « High-coercivity
    copper-rich Nd-Fe-B magnets by powder bed fusion using laser beam method », Additive
    Manufacturing, vol. 64, p. 103426, févr. 2023, doi: 10.1016/j.addma.2023.103426.\r\n[2]
    J. Wu et al., « Amorphous-crystalline nanostructured Nd-Fe-B permanent magnets
    using laser powder bed fusion: Metallurgy and magnetic properties », Acta Materialia,
    vol. 259, p. 119239, oct. 2023, doi: 10.1016/j.actamat.2023.119239.\r\n[3] W.
    F. Li, T. Ohkubo, T. Akiya, H. Kato, et K. Hono, « The role of Cu addition in
    the coercivity enhancement of sintered Nd-Fe-B permanent magnets», Journal of
    Materials Research, vol. 24, no 2, p. 413-420, feb. 2009, doi: 10.1557/JMR.2009.0041.\r\n[4]
    Y. Shinba, T. J. Konno, K. Ishikawa, K. Hiraga, et M. Sagawa, « Transmission electron
    microscopy study on Nd-rich phase and grain boundary structure of Nd–Fe–B sintered
    magnets », Journal of Applied Physics, vol. 97, no 5, p. 053504, févr. 2005, doi:
    10.1063/1.1851017.\r\n[5] A. Wolz, R. Caniou, O. Tosoni, C. Rado, et J.-P. Garandet,
    « On the Effect of Cooling Parameters on Solidification Structure in NdFeB Alloys
    », Advanced Engineering Materials, vol. n/a, no n/a, p. 2400978, doi: 10.1002/adem.202400978."
  description_type: abstract
  lang: en

## Creator

- name: Aymeric Wolz
  role: author
  organization: CEA (French Alternative Energies and Atomic Energy Commission), France
- name: Jean-Paul Garandet
  role: author
  organization: CEA (French Alternative Energies and Atomic Energy Commission), France
- name: Camille Flament
  role: author
  organization: CEA (French Alternative Energies and Atomic Energy Commission), France
- name: Olivier Tosoni
  role: author
  organization: CEA (French Alternative Energies and Atomic Energy Commission), France

## Contact agent



## Publisher

organization: National Institute for Materials Science (NIMS)

## Managing organization



## Keyword

- subject: REPM2025
  schema: not_defined
- subject: Laser Powder Bed Fusion (LPBF)
  schema: not_defined
- subject: Additive manufacturing
  schema: not_defined
- subject: NdFeB
  schema: not_defined
- subject: Microstructure investigation
  schema: not_defined
- subject: Columnar to equiaxed transition (CET)
  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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## Thumbnail

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filename: REPM2025_O11-4_Wolz.pdf