Downloads provided by UsageCountsField enhancement of a 12.5-T magnet using holmium poles
Copyright policy ) Hoard, R. W.; Mance, S. C.; Leber, R. L.; Dalder, E. N.; Chaplin, M. R.; Blair, K.; Nelson, D. H.; +1 Authors
Hoard, R. W.; Mance, S. C.; Leber, R. L.; Dalder, E. N.; Chaplin, M. R.; Blair, K.; Nelson, D. H.; Van Dyke, D. A.;
Field enhancement of a 12.5-T magnet using holmium poles
Unlike conventional ferromagnetic materials such as iron and Supermendur, which produce saturation magnetization fields of approximately 2 T, several of the rare-earth elements (holmium, terbium, erbium, gadolinium, and dysprosium) yield saturated fields of nearly 4 T. This property makes these rare-earth metals particularly attractive as flux concentrators for use in superconducting magnets. This report concerns the use of holmium inserts to enhance the peak useful field of the nominally 12.5-T, 5-cm-bore tape magnet manufactured by the Intermagnetics General Corporation (IGC). Nonlinear magnetostatic analysis indicates that this field increases to nearly 16 T with the rare-earth poles inserted within the bore on both sides of the coil's split-plane radial access gap. This paper focuses on computer modeling methods and experimental results.
United States
- University of North Texas United States
- Lawrence Livermore National Laboratory United States
- Lawrence Berkeley National Laboratory United States
Electrical Equipment, General Physics, Modifications, Equipment, Magnetic Flux, Elements, Electromagnets, Superconducting Magnets, Holmium, Rare Earths, Metals, Magnets, Superconducting Devices 420201* -- Engineering-- Cryogenic Equipment & Devices, 71 Classical And Quantum Mechanics
Electrical Equipment, General Physics, Modifications, Equipment, Magnetic Flux, Elements, Electromagnets, Superconducting Magnets, Holmium, Rare Earths, Metals, Magnets, Superconducting Devices 420201* -- Engineering-- Cryogenic Equipment & Devices, 71 Classical And Quantum Mechanics
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