Daniel N. Blaschke, John S. Carpenter, Abigail Hunter
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Predicting electrical conductivity in bi-metal composites
Generating high magnetic fields requires materials with not only high
electric conductivity, but also good strength properties in order to withstand
the necessarily strong Lorentz forces. A number of bi-metal composites, most
notably Cu/Nb, are considered to be good candidates for this purpose. Here, we
generalize our previous work on Cu/Nb in order to predict, from theory, the
dependence of electric conductivity on the microstructure and volume fraction
of the less conductive component for a number of other bi-metal composites.
Together with information on strength properties (taken from previous
literature), the conductivity information we provide in this work can help to
identify new promising candidate materials for magnet applications with the
highest achievable field strengths.
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