High performance magnet: Refractory metal and Fe-alloyed Ce2Co17 CMI research at Oak Ridge National Laboratory used first principles calculations to find large uniaxial magnetic anisotropy with magnetizations
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
