Half-metallic Antiferromagnet BaCrFeAs2

Akai H.; Bergqvist L.; Blöchl P. E.; Galanakis I.; Huang Q.; Kamihara Y.; Kresse G.; Kresse G.; Ködderitzsch D.; Lee C.-C.; Mostofi A. A.; Nakao M.; Nakao M.; Nie Y.-M.; Pardo V.; Park J. H.; Park M. S.; Park M. S.; Perdew J. P.; Pickett W. E.; Pickett W. E.; Rotter M.; Sefat A. S.; Singh D. J.; Torikachvili M. S.; Uehara M.; van Leuken H.; Wang Y. K.; Wang Y. K.; Wurmehl S.

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Half-metallic Antiferromagnet BaCrFeAs2

Authors: Akai H.
Bergqvist L.
Blöchl P. E.
Galanakis I.
Huang Q.
Kamihara Y.
Kresse G.
Kresse G.
Ködderitzsch D.
Lee C.-C.
Mostofi A. A.
Nakao M.
Nakao M.
Nie Y.-M.
Pardo V.
Park J. H.
Park M. S.
Park M. S.
Perdew J. P.
Pickett W. E.
Pickett W. E.
Rotter M.
Sefat A. S.
Singh D. J.
Torikachvili M. S.
Uehara M.
van Leuken H.
Wang Y. K.
Wang Y. K.
Wurmehl S.
Publication date: 18 July 2010
Publisher: 'American Chemical Society (ACS)'
Doi

Abstract

First-principles calculations and a tight-binding analysis predict that the iron-pnictide BaCrFeAs2 is a promising candidate for half-metallic material with fully-compensated magnetization. The transition-metal ions Cr and Fe prefer the three-dimensional intervening lattice, which yields the antiferromagnetic order of spin orientations. Due to the difference between Cr and Fe in the electronegativity, a band gap is opened at the Fermi level in the spin channel in which Fe provides the majority carriers. The selective hybridization between 3d orbitals of Cr and As:4p states due to the peculiar lattice structure of the iron-pnictide is shown to be crucial for the novel properties.Comment: added reference

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