Morphotropic phase boundaries in ferromagnets: Tb1-xDy xFe2 alloys

Richard Bergstrom; Manfred Wuttig; James Cullen; Peter Zavalij; Robert Briber; Cindi Dennis; V. Ovidiu Garlea; Mark Laver

doi:10.1103/PhysRevLett.111.017203

Morphotropic phase boundaries in ferromagnets: Tb_1-xDy _xFe₂ alloys

Richard Bergstrom, Manfred Wuttig, James Cullen, Peter Zavalij, Robert Briber, Cindi Dennis, V. Ovidiu Garlea, Mark Laver

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64 Scopus citations

Abstract

The structure and properties of the ferromagnet Tb_1-xDy _xFe₂ are explored through the morphotropic phase boundary (MPB) separating ferroic phases of differing symmetry. Our synchrotron data support a first order structural transition, with a broadening MPB width at higher temperatures. The optimal point for magnetomechanical applications is not centered on the MPB but lies on the rhombohedral side, where the high striction of the rhombohedral majority phase combines with the softened anisotropy of the MPB. We compare our findings with single ion crystal field theory and with ferroelectric MPBs, where the controlling energies are different.

Original language	English
Article number	017203
Journal	Physical Review Letters
Volume	111
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevLett.111.017203
State	Published - Jul 3 2013

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abstract = "The structure and properties of the ferromagnet Tb1-xDy xFe2 are explored through the morphotropic phase boundary (MPB) separating ferroic phases of differing symmetry. Our synchrotron data support a first order structural transition, with a broadening MPB width at higher temperatures. The optimal point for magnetomechanical applications is not centered on the MPB but lies on the rhombohedral side, where the high striction of the rhombohedral majority phase combines with the softened anisotropy of the MPB. We compare our findings with single ion crystal field theory and with ferroelectric MPBs, where the controlling energies are different.",

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AU - Garlea, V. Ovidiu

AU - Laver, Mark

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AB - The structure and properties of the ferromagnet Tb1-xDy xFe2 are explored through the morphotropic phase boundary (MPB) separating ferroic phases of differing symmetry. Our synchrotron data support a first order structural transition, with a broadening MPB width at higher temperatures. The optimal point for magnetomechanical applications is not centered on the MPB but lies on the rhombohedral side, where the high striction of the rhombohedral majority phase combines with the softened anisotropy of the MPB. We compare our findings with single ion crystal field theory and with ferroelectric MPBs, where the controlling energies are different.

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Morphotropic phase boundaries in ferromagnets: Tb_1-xDy _xFe₂ alloys

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