Optimization of Alnico’s Processing Route to Enhance Magnetic Properties

Additional Funding Sources

The project described was supported by the Ronald E. McNair Post-Baccalaureate Achievement Program through the U.S. Department of Education under Award No. P217A170273.

Abstract

Growing concerns for carbon emissions and the rising cost of petroleum has increased interest into finding alternatives to fossil fuel–based energy resources. Current sustainability efforts using electric vehicles rely on strong permanent magnets (PM) to work efficiently and rare earth (RE) metals make the best PM. Due to short supply of RE metals, efforts for developing non-RE PM to meet the demand of traction motors is a major focus of scientific and engineering communities. Alnico alloy (Fe, Al, Ni, Co, etc.) is an attractive near-term solution. However, Alnico’s magnetic properties are not as competitive as RE PM. Theoretically, Alnico can produce similar magnetic strength than RE PM, with proper microstructure optimization. In this effort, we will develop a physics-based mesoscale model to gain insight into the manufacturing process of Alnico, including thermal magnetic treatment along with spinodal decomposition, to optimize the processing route to maximize Alnico’s magnetic strength.

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Optimization of Alnico’s Processing Route to Enhance Magnetic Properties

Growing concerns for carbon emissions and the rising cost of petroleum has increased interest into finding alternatives to fossil fuel–based energy resources. Current sustainability efforts using electric vehicles rely on strong permanent magnets (PM) to work efficiently and rare earth (RE) metals make the best PM. Due to short supply of RE metals, efforts for developing non-RE PM to meet the demand of traction motors is a major focus of scientific and engineering communities. Alnico alloy (Fe, Al, Ni, Co, etc.) is an attractive near-term solution. However, Alnico’s magnetic properties are not as competitive as RE PM. Theoretically, Alnico can produce similar magnetic strength than RE PM, with proper microstructure optimization. In this effort, we will develop a physics-based mesoscale model to gain insight into the manufacturing process of Alnico, including thermal magnetic treatment along with spinodal decomposition, to optimize the processing route to maximize Alnico’s magnetic strength.