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Hybrid High-Temperature Nanostructured Magnets

Published online by Cambridge University Press:  21 March 2011

David J. Sellmyer
Affiliation:
Behlen Laboratory of Physics and Center for Materials Research and AnalysisUniversity of NebraskaLincoln, NE 68588-0113, USA
J. Zhou
Affiliation:
Behlen Laboratory of Physics and Center for Materials Research and AnalysisUniversity of NebraskaLincoln, NE 68588-0113, USA
H. Tang
Affiliation:
Behlen Laboratory of Physics and Center for Materials Research and AnalysisUniversity of NebraskaLincoln, NE 68588-0113, USA
R. Skomski
Affiliation:
Behlen Laboratory of Physics and Center for Materials Research and AnalysisUniversity of NebraskaLincoln, NE 68588-0113, USA
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Abstract

The hysteretic behavior of two-phase permanent magnets for high-temperature applications is examined. A variety of systems have been synthesized and investigated, including Sm-Co-Cu-Ti bulk magnets, SmCo5:Cu-Ti thin-film materials, and mechanically milled Sm-CoZr magnets. The hybrid character of the material leads to very high room-temperature coercivities, between 30.2 and 43.6 kOe, and to the survival of a comparatively large part of the coercivity at high temperatures (12.3 kOe at 500 °C for SmCo 6.5Cu0.8Ti0.3). The coercivity reflects the structure and chemical composition of the material. When ferromagnetic grains are separated by a ferromagnetic boundary phase, the boundary phase acts as a pinning center, but when the grain-boundary phase has a comparatively low Curie temperature, the high-temperature magnetism of the system is that of a weakly interacting ensemble of magnetic particles. In spite of some residual paramagnetic exchange coupling, which is discussed in this work, this mechanism enhances the coercivity.

Type
Research Article
Copyright
Copyright © Materials Research Society 2001

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References

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