News & Highlights
Giant magnetic anisotropy in cerium-substituted hexaferrite
Science News: How rare earth elements’ hidden properties make modern technology possible
Prediction of high magnetic anisotropy material CeZrFe11
Reduced cobalt formulation of CMI “gap magnet” material CeCo5
A well-known iron-based magnet is also a potential quantum information material
Durga Paudyal at Ames Laboratory leads the CMI project "Predicting magnetic anisotropy"
This project identifies, develops and employs novel methods to exploit f-elements for use in various novel rare earth lean magnet materials and d-elements for use in improved rare earth free permanent magnet materials by applying advanced theoretical and computational techniques. The research with rare earth lean materials aims at improving permanent magnet performance beyond the current champion neo-magnets while research with rare earth free materials aims at improving permanent magnet performance at the gap magnet level. The overarching objective is to provide theoretical support and guidance to various experimental magnet thrust projects to discover and develop high performance magnets.
Mentoring: CMI project lead Durga Paudyal mentors SCGSR awardee