High-performance critical-element-free permanent magnets CMI research at Ames Laboratory demonstrated that mechanochemical preprocessing is beneficial for nitrogen insertion/topotactic extraction
Lower-cost commercial grade Ce enhances performance and reduces cost in gap magnets CMI research with lower-cost commercial grade cerium enhances performance and reduces cost in gap magnets. Also, the less costly “dirty” cerium samples showed as much as a 5% increase of both coercivity and magnetization, resulting in better energy product.
Discovery of the large coercivity CeCo5 – CeZn5 system CMI researchers discover the large coercivity CeCo5 – CeZn5 system
Development of a new rare earth-free permanent magnet based on Sb-doped Fe3Sn CMI research on development of a new rare earth-free permanent magnet based on Sb-doped Fe3Sn
Predicting mechanical performance of Sm-Co magnets CMI research predicts mechanical performance of Sm-Co magnets
Electromagnet core design enable printed anisotropic magnets CMI research at Ames Laboratory and ORNL on electromagnet core design enable printed anisotropic magnets
Mn4+ red phosphors for improved LEDs CMI research on phosphors for lighting led to a new red phosphor for improved LEDs
Unprecedented intra-lanthanide separation achieved CMI research has achieved unprecedented intra-lanthanide separation
Performance analysis of Cd-Co-Cu magnets in electric drive CMI research analyzed performance of Cd-Co-Cu magnets in electric drive
Recycled additively manufactured printed rare earth magnets with no wastage CMI reseachers at Ames Laboratory and Oak Ridge National Laboratory collaborated on recycled additively manufactured (AM) printed rare earth (RE) magnets with no wastage
