Sm2Fe17N3 as a cost-effective high-performance magnet

image of a line graph showing powder X-ray diffraction patterns of as-washed and sintered material.
Powder X-ray diffraction patterns of as-washed and sintered material.

CMI researchers from Ames National Laboratory conducted the research for this highlight.

Innovation
Direct conversion of Sm2O3 into Sm2Fe17 phase via reduction-diffusion approach produces nearly oxygen-free, sinterable Sm2Fe17N3 powders

Achievement
Magnet sintered at 420°C reaches a record relative density of 89% and demonstrates excellent hard-magnetic properties: remanence, Mr = 11.5 kG, and energy product BHmax = 23.5 MGOe. 

Significance and Impact

  • Criticality and cost: the material is mostly Fe (~74% wt.%) and it contains non-critical rare earth, Sm, as well as other earth-abundant constituents
  • When fully developed, thermally-stable Sm2Fe17N3–based materials are expected to become competitive with Nd2Fe14B-based magnets

Hub Goal Addressed 
Reducing critical rare-earth content in permanent magnets via development of novel sinterable hard-magnetic materials. 

Hysteresis loops of corresponding samples.
Hysteresis loops of corresponding samples.