Epitaxial stabilization of ferromagnetism in the nanophase of FeGe

Changgan Zeng; P. R.C. Kent; M. Varela; M. Eisenbach; G. M. Stocks; Maria Torija; Jian Shen; Hanno H. Weitering

doi:10.1103/PhysRevLett.96.127201

Epitaxial stabilization of ferromagnetism in the nanophase of FeGe

Changgan Zeng, P. R.C. Kent, M. Varela, M. Eisenbach, G. M. Stocks, Maria Torija, Jian Shen, Hanno H. Weitering

Computational Chemistry and Nanomaterial

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

Epitaxial nanocrystals of FeGe have been stabilized on Ge(111). The nanocrystals assume a quasi-one-dimensional shape as they grow exclusively along the 11̄0 direction of the Ge(111) substrate, culminating in a compressed monoclinic modification of FeGe. Whereas monoclinic FeGe is antiferromagnetic in the bulk, the nanowires are surprisingly strong ferromagnets below ∼200K with an average magnetic moment of 0.8μB per Fe atom. Density functional calculations indicate an unusual stabilization mechanism for the observed ferromagnetism: lattice compression destabilizes the antiferromagnetic Peierls-like ground state observed in the bulk while increased p-d hybridization suppresses the magnetic moments and stabilizes ferromagnetism.

Original language	English
Article number	127201
Journal	Physical Review Letters
Volume	96
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevLett.96.127201
State	Published - 2006

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title = "Epitaxial stabilization of ferromagnetism in the nanophase of FeGe",

abstract = "Epitaxial nanocrystals of FeGe have been stabilized on Ge(111). The nanocrystals assume a quasi-one-dimensional shape as they grow exclusively along the 1{\=1}0 direction of the Ge(111) substrate, culminating in a compressed monoclinic modification of FeGe. Whereas monoclinic FeGe is antiferromagnetic in the bulk, the nanowires are surprisingly strong ferromagnets below ∼200K with an average magnetic moment of 0.8μB per Fe atom. Density functional calculations indicate an unusual stabilization mechanism for the observed ferromagnetism: lattice compression destabilizes the antiferromagnetic Peierls-like ground state observed in the bulk while increased p-d hybridization suppresses the magnetic moments and stabilizes ferromagnetism.",

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T1 - Epitaxial stabilization of ferromagnetism in the nanophase of FeGe

AU - Zeng, Changgan

AU - Kent, P. R.C.

AU - Varela, M.

AU - Eisenbach, M.

AU - Stocks, G. M.

AU - Torija, Maria

AU - Shen, Jian

AU - Weitering, Hanno H.

PY - 2006

Y1 - 2006

N2 - Epitaxial nanocrystals of FeGe have been stabilized on Ge(111). The nanocrystals assume a quasi-one-dimensional shape as they grow exclusively along the 11̄0 direction of the Ge(111) substrate, culminating in a compressed monoclinic modification of FeGe. Whereas monoclinic FeGe is antiferromagnetic in the bulk, the nanowires are surprisingly strong ferromagnets below ∼200K with an average magnetic moment of 0.8μB per Fe atom. Density functional calculations indicate an unusual stabilization mechanism for the observed ferromagnetism: lattice compression destabilizes the antiferromagnetic Peierls-like ground state observed in the bulk while increased p-d hybridization suppresses the magnetic moments and stabilizes ferromagnetism.

AB - Epitaxial nanocrystals of FeGe have been stabilized on Ge(111). The nanocrystals assume a quasi-one-dimensional shape as they grow exclusively along the 11̄0 direction of the Ge(111) substrate, culminating in a compressed monoclinic modification of FeGe. Whereas monoclinic FeGe is antiferromagnetic in the bulk, the nanowires are surprisingly strong ferromagnets below ∼200K with an average magnetic moment of 0.8μB per Fe atom. Density functional calculations indicate an unusual stabilization mechanism for the observed ferromagnetism: lattice compression destabilizes the antiferromagnetic Peierls-like ground state observed in the bulk while increased p-d hybridization suppresses the magnetic moments and stabilizes ferromagnetism.

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Epitaxial stabilization of ferromagnetism in the nanophase of FeGe

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