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

24 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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10.1103/PhysRevLett.96.127201

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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.",

author = "Changgan Zeng and Kent, \{P. R.C.\} and M. Varela and M. Eisenbach and Stocks, \{G. M.\} and Maria Torija and Jian Shen and Weitering, \{Hanno H.\}",

year = "2006",

doi = "10.1103/PhysRevLett.96.127201",

language = "English",

volume = "96",

journal = "Physical Review Letters",

issn = "0031-9007",

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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.

UR - https://www.scopus.com/pages/publications/33645314050

U2 - 10.1103/PhysRevLett.96.127201

DO - 10.1103/PhysRevLett.96.127201

M3 - Article

AN - SCOPUS:33645314050

SN - 0031-9007

VL - 96

JO - Physical Review Letters

JF - Physical Review Letters

IS - 12

M1 - 127201

ER -

Epitaxial stabilization of ferromagnetism in the nanophase of FeGe

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